/*****************************************************************************

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This program is free software; you can redistribute it and/or modify it under
the terms of the GNU General Public License, version 2.0, as published by the
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*****************************************************************************/

#include "my_dbug.h"

/** @file dict/dict0stats.cc
 Code used for calculating and manipulating table statistics.

 Created Jan 06, 2010 Vasil Dimov
 *******************************************************/

#include <mysql_com.h>
#include <algorithm>
#include <map>
#include <vector>

#include <scope_guard.h>
#include "dict0stats.h"
#include "dyn0buf.h"
#include "ha_prototypes.h"
#include "lob0lob.h"
#include "log0chkp.h"
#include "m_string.h"
#include "pars0pars.h"
#include "row0sel.h"
#include "sql/debug_sync.h"
#include "trx0trx.h"
#include "univ.i"
#include "ut0new.h"
#include "ut0rnd.h"
#include "ut0ut.h"

#ifndef __FILE_NAME__
#define __FILE_NAME__ "dict0stats.cc"
#endif

/* Sampling algorithm description @{

The algorithm is controlled by one number - N_SAMPLE_PAGES(index),
let it be A, which is the number of leaf pages to analyze for a given index
for each n-prefix (if the index is on 3 columns, then 3*A leaf pages will be
analyzed).

Let the total number of leaf pages in the table be T.
Level 0 - leaf pages, level H - root.

Definition: N-prefix-boring record is a record on a non-leaf page that equals
the next (to the right, cross page boundaries, skipping the supremum and
infimum) record on the same level when looking at the fist n-prefix columns.
The last (user) record on a level is not boring (it does not match the
non-existent user record to the right). We call the records boring because all
the records on the page below a boring record are equal to that boring record.

We avoid diving below boring records when searching for a leaf page to
estimate the number of distinct records because we know that such a leaf
page will have number of distinct records == 1.

For each n-prefix: start from the root level and full scan subsequent lower
levels until a level that contains at least A*10 distinct records is found.
Lets call this level LA.
As an optimization the search is canceled if it has reached level 1 (never
descend to the level 0 (leaf)) and also if the next level to be scanned
would contain more than A pages. The latter is because the user has asked
to analyze A leaf pages and it does not make sense to scan much more than
A non-leaf pages with the sole purpose of finding a good sample of A leaf
pages.

After finding the appropriate level LA with >A*10 distinct records (or less in
the exceptions described above), divide it into groups of equal records and
pick A such groups. Then pick the last record from each group. For example,
let the level be:

index:  0,1,2,3,4,5,6,7,8,9,10
record: 1,1,1,2,2,7,7,7,7,7,9

There are 4 groups of distinct records and if A=2 random ones are selected,
e.g. 1,1,1 and 7,7,7,7,7, then records with indexes 2 and 9 will be selected.

After selecting A records as described above, dive below them to find A leaf
pages and analyze them, finding the total number of distinct records. The
dive to the leaf level is performed by selecting a non-boring record from
each page and diving below it.

This way, a total of A leaf pages are analyzed for the given n-prefix.

Let the number of different key values found in each leaf page i be Pi (i=1..A).
Let N_DIFF_AVG_LEAF be (P1 + P2 + ... + PA) / A.
Let the number of different key values on level LA be N_DIFF_LA.
Let the total number of records on level LA be TOTAL_LA.
Let R be N_DIFF_LA / TOTAL_LA, we assume this ratio is the same on the
leaf level.
Let the number of leaf pages be N.
Then the total number of different key values on the leaf level is:
N * R * N_DIFF_AVG_LEAF.
See REF01 for the implementation.

The above describes how to calculate the cardinality of an index.
This algorithm is executed for each n-prefix of a multi-column index
where n=1..n_uniq.
@} */

/* names of the tables from the persistent statistics storage */
#define TABLE_STATS_NAME "mysql/innodb_table_stats"
#define TABLE_STATS_NAME_PRINT "mysql.innodb_table_stats"
#define INDEX_STATS_NAME "mysql/innodb_index_stats"
#define INDEX_STATS_NAME_PRINT "mysql.innodb_index_stats"

#ifdef UNIV_STATS_DEBUG
#define DEBUG_PRINTF(fmt, ...) printf(fmt, ##__VA_ARGS__)
#else                          /* UNIV_STATS_DEBUG */
#define DEBUG_PRINTF(fmt, ...) /* noop */
#endif                         /* UNIV_STATS_DEBUG */

/* Gets the number of leaf pages to sample in persistent stats estimation */
#define N_SAMPLE_PAGES(index)                                    \
  static_cast<uint64_t>((index)->table->stats_sample_pages != 0  \
                            ? (index)->table->stats_sample_pages \
                            : srv_stats_persistent_sample_pages)

/* number of distinct records on a given level that are required to stop
descending to lower levels and fetch N_SAMPLE_PAGES(index) records
from that level */
#define N_DIFF_REQUIRED(index) (N_SAMPLE_PAGES(index) * 10)

/* A dynamic array where we store the boundaries of each distinct group
of keys. For example if a btree level is:
index: 0,1,2,3,4,5,6,7,8,9,10,11,12
data:  b,b,b,b,b,b,g,g,j,j,j, x, y
then we would store 5,7,10,11,12 in the array. */
typedef std::vector<uint64_t, ut::allocator<uint64_t>> boundaries_t;

/** Allocator type used for index_map_t. */
typedef ut::allocator<std::pair<const char *const, dict_index_t *>>
    index_map_t_allocator;

/** Auxiliary map used for sorting indexes by name in dict_stats_save(). */
typedef std::map<const char *, dict_index_t *, ut_strcmp_functor,
                 index_map_t_allocator>
    index_map_t;

/** Checks whether an index should be ignored in stats manipulations:
 - stats fetch
 - stats recalc
 - stats save
 @return true if exists and all tables are ok */
static inline bool dict_stats_should_ignore_index(
    const dict_index_t *index) /*!< in: index */
{
  return ((index->type & DICT_FTS) || index->is_corrupted() ||
          dict_index_is_spatial(index) || index->to_be_dropped ||
          !index->is_committed());
}

/** Executes a given SQL statement using the InnoDB internal SQL parser.
This function will free the pinfo object.
@param[in,out]  pinfo   pinfo to pass to que_eval_sql() must already
have any literals bound to it
@param[in]      sql   SQL string to execute
@param[in,out]  trx   in case of NULL the function will allocate and free the
                      trx object.
@return DB_SUCCESS or error code */
static dberr_t dict_stats_exec_sql(pars_info_t *pinfo, const char *sql,
                                   trx_t *trx) {
  dberr_t err;
  const bool trx_started = (trx == nullptr);

  ut_ad(rw_lock_own(dict_operation_lock, RW_LOCK_X));
  ut_ad(!dict_sys_mutex_own());

  if (trx == nullptr) {
    trx = trx_allocate_for_background();

    if (srv_read_only_mode) {
      trx_start_internal_read_only(trx, UT_LOCATION_HERE);
    } else {
      trx_start_internal(trx, UT_LOCATION_HERE);
    }
  }

  err = que_eval_sql(pinfo, sql, trx); /* pinfo is freed here */

  DBUG_EXECUTE_IF("dict_stats_exec_sql_lock_timeout", {
    static thread_local int execution_counter{0};

    execution_counter++;

    err = DB_LOCK_WAIT_TIMEOUT;
    if (execution_counter > 3) {
      DBUG_SET("-d,dict_stats_exec_sql_lock_timeout");
    }
  });

  DBUG_EXECUTE_IF(
      "stats_index_error", if (!trx_started) {
        err = DB_STATS_DO_NOT_EXIST;
        trx->error_state = DB_STATS_DO_NOT_EXIST;
      });

  if (!trx_started) {
    return err;
  }

  if (err == DB_SUCCESS) {
    trx_commit_for_mysql(trx);
  } else {
    trx->op_info = "rollback of internal trx on stats tables";
    trx->dict_operation_lock_mode = RW_X_LATCH;
    trx_rollback_to_savepoint(trx, nullptr);
    trx->dict_operation_lock_mode = 0;
    trx->op_info = "";
    ut_a(trx->error_state == DB_SUCCESS);
  }

  trx_free_for_background(trx);

  return (err);
}

/** Duplicate a table object and its indexes.
 This function creates a dummy dict_table_t object and initializes the
 following table and index members:
 dict_table_t::id (copied)
 dict_table_t::heap (newly created)
 dict_table_t::name (copied)
 dict_table_t::corrupted (copied)
 dict_table_t::indexes<> (newly created)
 dict_table_t::magic_n
 for each entry in dict_table_t::indexes, the following are initialized:
 (indexes that have DICT_FTS set in index->type are skipped)
 dict_index_t::id (copied)
 dict_index_t::name (copied)
 dict_index_t::table_name (points to the copied table name)
 dict_index_t::table (points to the above semi-initialized object)
 dict_index_t::type (copied)
 dict_index_t::to_be_dropped (copied)
 dict_index_t::online_status (copied)
 dict_index_t::n_uniq (copied)
 dict_index_t::fields[] (newly created, only first n_uniq, only fields[i].name)
 dict_index_t::indexes<> (newly created)
 dict_index_t::stat_n_diff_key_vals[] (only allocated, left uninitialized)
 dict_index_t::stat_n_sample_sizes[] (only allocated, left uninitialized)
 dict_index_t::stat_n_non_null_key_vals[] (only allocated, left uninitialized)
 dict_index_t::magic_n
 The returned object should be freed with dict_stats_table_clone_free()
 when no longer needed.
 @return incomplete table object */
static dict_table_t *dict_stats_table_clone_create(
    const dict_table_t *table) /*!< in: table whose stats to copy */
{
  size_t heap_size;
  const dict_index_t *index;

  /* Estimate the size needed for the table and all of its indexes */

  heap_size = 0;
  heap_size += sizeof(dict_table_t);
  heap_size += strlen(table->name.m_name) + 1;

  for (index = table->first_index(); index != nullptr; index = index->next()) {
    if (dict_stats_should_ignore_index(index)) {
      continue;
    }

    ut_ad(!dict_index_is_ibuf(index));

    ulint n_uniq = dict_index_get_n_unique(index);

    heap_size += sizeof(dict_index_t);
    heap_size += strlen(index->name) + 1;
    heap_size += n_uniq * sizeof(index->fields[0]);
    for (ulint i = 0; i < n_uniq; i++) {
      heap_size += strlen(index->fields[i].name) + 1;
    }
    heap_size += n_uniq * sizeof(index->stat_n_diff_key_vals[0]);
    heap_size += n_uniq * sizeof(index->stat_n_sample_sizes[0]);
    heap_size += n_uniq * sizeof(index->stat_n_non_null_key_vals[0]);
  }

  /* Allocate the memory and copy the members */

  mem_heap_t *heap;

  heap = mem_heap_create(heap_size, UT_LOCATION_HERE);

  dict_table_t *t;

  t = (dict_table_t *)mem_heap_alloc(heap, sizeof(*t));

  UNIV_MEM_ASSERT_RW_ABORT(&table->id, sizeof(table->id));
  t->id = table->id;

  t->heap = heap;

  t->name.m_name = mem_heap_strdup(heap, table->name.m_name);

  /* This private object "t" is not shared with other threads, so
  we do not need the stats_latch and stats_compute_mutex (thus we pass false
  below). The dict_table_stats_lock()/unlock()
  dict_table_stats_compute_lock()/unlock() routines will do nothing. */
  dict_table_stats_latch_create_lazy(t, false);
  dict_table_stats_compute_mutex_create_lazy(t, false);

  UT_LIST_INIT(t->indexes);

  for (index = table->first_index(); index != nullptr; index = index->next()) {
    if (dict_stats_should_ignore_index(index)) {
      continue;
    }

    ut_ad(!dict_index_is_ibuf(index));

    dict_index_t *idx;

    idx = (dict_index_t *)mem_heap_alloc(heap, sizeof(*idx));

    UNIV_MEM_ASSERT_RW_ABORT(&index->id, sizeof(index->id));
    idx->id = index->id;
    idx->space = index->space;

    idx->name = mem_heap_strdup(heap, index->name);

    idx->table_name = t->name.m_name;

    idx->table = t;

    idx->type = index->type;

    idx->to_be_dropped = 0;

    idx->online_status = ONLINE_INDEX_COMPLETE;
    idx->set_committed(true);

    idx->n_uniq = index->n_uniq;

    idx->fields = (dict_field_t *)mem_heap_alloc(
        heap, idx->n_uniq * sizeof(idx->fields[0]));

    for (ulint i = 0; i < idx->n_uniq; i++) {
      idx->fields[i].name = mem_heap_strdup(heap, index->fields[i].name);
    }

    /* hook idx into t->indexes */
    UT_LIST_ADD_LAST(t->indexes, idx);

    idx->stat_n_diff_key_vals = (uint64_t *)mem_heap_alloc(
        heap, idx->n_uniq * sizeof(idx->stat_n_diff_key_vals[0]));

    idx->stat_n_sample_sizes = (uint64_t *)mem_heap_alloc(
        heap, idx->n_uniq * sizeof(idx->stat_n_sample_sizes[0]));

    idx->stat_n_non_null_key_vals = (uint64_t *)mem_heap_alloc(
        heap, idx->n_uniq * sizeof(idx->stat_n_non_null_key_vals[0]));
    ut_d(idx->magic_n = DICT_INDEX_MAGIC_N);
  }

  ut_d(t->magic_n = DICT_TABLE_MAGIC_N);

  return (t);
}

/** Free the resources occupied by an object returned by
 dict_stats_table_clone_create(). */
static void dict_stats_table_clone_free(
    dict_table_t *t) /*!< in: dummy table object to free */
{
  dict_table_stats_latch_destroy(t);
  dict_table_stats_compute_mutex_destroy(t);
  mem_heap_free(t->heap);
}

/** Write all zeros (or 1 where it makes sense) into an index
 statistics members. The resulting stats correspond to an empty index.
 The caller must own index's table stats latch in X mode
 (dict_table_stats_lock(table, RW_X_LATCH)) */
static void dict_stats_empty_index(dict_index_t *index) /*!< in/out: index */
{
  ut_ad(!(index->type & DICT_FTS));
  ut_ad(!dict_index_is_ibuf(index));

  ulint n_uniq = index->n_uniq;

  for (ulint i = 0; i < n_uniq; i++) {
    index->stat_n_diff_key_vals[i] = 0;
    index->stat_n_sample_sizes[i] = 1;
    index->stat_n_non_null_key_vals[i] = 0;
  }

  index->stat_index_size = 1;
  index->stat_n_leaf_pages = 1;
}

/** Write all zeros (or 1 where it makes sense) into a table and its indexes'
 statistics members. The resulting stats correspond to an empty table. */
static void dict_stats_empty_table(dict_table_t *table) /*!< in/out: table */
{
  /* Zero the stats members */

  dict_table_stats_lock(table, RW_X_LATCH);

  table->stat_n_rows = 0;
  table->stat_clustered_index_size = 1;
  /* 1 page for each index, not counting the clustered */
  table->stat_sum_of_other_index_sizes = UT_LIST_GET_LEN(table->indexes) - 1;
  table->stat_modified_counter = 0;

  for (auto index : table->indexes) {
    if (index->type & DICT_FTS) {
      continue;
    }

    ut_ad(!dict_index_is_ibuf(index));

    dict_stats_empty_index(index);
  }

  table->stat_initialized = true;

  dict_table_stats_unlock(table, RW_X_LATCH);
}

/** Check whether table's stats are initialized (assert if they are not). */
static void dict_stats_assert_initialized(
    const dict_table_t *table) /*!< in: table */
{
  ut_a(table->stat_initialized);

  UNIV_MEM_ASSERT_RW_ABORT(&table->stats_last_recalc,
                           sizeof(table->stats_last_recalc));

  UNIV_MEM_ASSERT_RW_ABORT(&table->stat_persistent,
                           sizeof(table->stat_persistent));

  UNIV_MEM_ASSERT_RW_ABORT(&table->stats_auto_recalc,
                           sizeof(table->stats_auto_recalc));

  UNIV_MEM_ASSERT_RW_ABORT(&table->stats_sample_pages,
                           sizeof(table->stats_sample_pages));

  UNIV_MEM_ASSERT_RW_ABORT(&table->stat_n_rows, sizeof(table->stat_n_rows));

  UNIV_MEM_ASSERT_RW_ABORT(&table->stat_clustered_index_size,
                           sizeof(table->stat_clustered_index_size));

  UNIV_MEM_ASSERT_RW_ABORT(&table->stat_sum_of_other_index_sizes,
                           sizeof(table->stat_sum_of_other_index_sizes));

  UNIV_MEM_ASSERT_RW_ABORT(&table->stat_modified_counter,
                           sizeof(table->stat_modified_counter));

  UNIV_MEM_ASSERT_RW_ABORT(&table->stats_bg_flag, sizeof(table->stats_bg_flag));

  for (const dict_index_t *index = table->first_index(); index != nullptr;
       index = index->next()) {
    if (!dict_stats_should_ignore_index(index)) {
      index->assert_stats_initialized();
    }
  }
}

#define INDEX_EQ(i1, i2)                                         \
  ((i1) != NULL && (i2) != NULL && (i1)->space == (i2)->space && \
   (i1)->id == (i2)->id && strcmp((i1)->name, (i2)->name) == 0)

/** Copy table and index statistics from one table to another, including index
 stats. Extra indexes in src are ignored and extra indexes in dst are
 initialized to correspond to an empty index. */
static void dict_stats_copy(dict_table_t *dst, /*!< in/out: destination table */
                            const dict_table_t *src) /*!< in: source table */
{
  dst->stats_last_recalc = src->stats_last_recalc;
  dst->stat_n_rows = src->stat_n_rows;
  dst->stat_clustered_index_size = src->stat_clustered_index_size;
  dst->stat_sum_of_other_index_sizes = src->stat_sum_of_other_index_sizes;
  dst->stat_modified_counter = src->stat_modified_counter;

  dict_index_t *dst_idx;
  const dict_index_t *src_idx;

  for (dst_idx = dst->first_index(), src_idx = src->first_index();
       dst_idx != nullptr; dst_idx = dst_idx->next()) {
    if (src_idx != nullptr) {
      src_idx = src_idx->next();
    }
    if (dict_stats_should_ignore_index(dst_idx)) {
      if (!(dst_idx->type & DICT_FTS)) {
        dict_stats_empty_index(dst_idx);
      }
      continue;
    }

    ut_ad(!dict_index_is_ibuf(dst_idx));

    if (!INDEX_EQ(src_idx, dst_idx)) {
      for (src_idx = src->first_index(); src_idx != nullptr;
           src_idx = src_idx->next()) {
        if (INDEX_EQ(src_idx, dst_idx)) {
          break;
        }
      }
    }

    if (!INDEX_EQ(src_idx, dst_idx)) {
      dict_stats_empty_index(dst_idx);
      continue;
    }

    ulint n_copy_el;

    if (dst_idx->n_uniq > src_idx->n_uniq) {
      n_copy_el = src_idx->n_uniq;
      /* Since src is smaller some elements in dst
      will remain untouched by the following memmove(),
      thus we init all of them here. */
      dict_stats_empty_index(dst_idx);
    } else {
      n_copy_el = dst_idx->n_uniq;
    }

    memmove(dst_idx->stat_n_diff_key_vals, src_idx->stat_n_diff_key_vals,
            n_copy_el * sizeof(dst_idx->stat_n_diff_key_vals[0]));

    memmove(dst_idx->stat_n_sample_sizes, src_idx->stat_n_sample_sizes,
            n_copy_el * sizeof(dst_idx->stat_n_sample_sizes[0]));

    memmove(dst_idx->stat_n_non_null_key_vals,
            src_idx->stat_n_non_null_key_vals,
            n_copy_el * sizeof(dst_idx->stat_n_non_null_key_vals[0]));

    dst_idx->stat_index_size = src_idx->stat_index_size;

    dst_idx->stat_n_leaf_pages = src_idx->stat_n_leaf_pages;
  }

  dst->stat_initialized = true;
}

/** Duplicate the stats of a table and its indexes.
This function creates a dummy dict_table_t object and copies the input
table's stats into it. The returned table object is not in the dictionary
cache and cannot be accessed by any other threads. In addition to the
members copied in dict_stats_table_clone_create() this function initializes
the following:
dict_table_t::stat_initialized
dict_table_t::stat_persistent
dict_table_t::stat_n_rows
dict_table_t::stat_clustered_index_size
dict_table_t::stat_sum_of_other_index_sizes
dict_table_t::stat_modified_counter
dict_index_t::stat_n_diff_key_vals[]
dict_index_t::stat_n_sample_sizes[]
dict_index_t::stat_n_non_null_key_vals[]
dict_index_t::stat_index_size
dict_index_t::stat_n_leaf_pages
The returned object should be freed with dict_stats_snapshot_free()
when no longer needed.
@param[in]      table   table whose stats to copy
@return incomplete table object */
static dict_table_t *dict_stats_snapshot_create(dict_table_t *table) {
  dict_sys_mutex_enter();

  dict_table_stats_lock(table, RW_S_LATCH);

  dict_stats_assert_initialized(table);

  dict_table_t *t;

  t = dict_stats_table_clone_create(table);

  dict_stats_copy(t, table);

  t->stat_persistent = table->stat_persistent;
  t->stats_auto_recalc = table->stats_auto_recalc;
  t->stats_sample_pages = table->stats_sample_pages;
  t->stats_bg_flag = table->stats_bg_flag;

  dict_table_stats_unlock(table, RW_S_LATCH);

  dict_sys_mutex_exit();

  return (t);
}

/** Free the resources occupied by an object returned by
 dict_stats_snapshot_create(). */
static void dict_stats_snapshot_free(
    dict_table_t *t) /*!< in: dummy table object to free */
{
  dict_stats_table_clone_free(t);
}

/** Empty index statistics structure values.
@param[in,out]  index_stats   index statistics to empty
@param[in]      index         index to get number of unique fields */
static void dict_stats_empty_index_stats(dict_index_stats_t *index_stats,
                                         dict_index_t *index) {
  ut_ad(!(index->type & DICT_FTS));
  ut_ad(!(index->type & DICT_IBUF));

  const size_t n_uniq = index->n_uniq;

  for (size_t i = 0; i < n_uniq; i++) {
    index_stats->n_diff_key_vals[i] = 0;
    index_stats->n_sample_sizes[i] = 1;
    index_stats->n_non_null_key_vals[i] = 0;
  }

  index_stats->index_size = 1;
  index_stats->n_leaf_pages = 1;
}

/**
Calculates the necessary size of heap to store dict_index_stats_t for the
given index.
@param[in] index index for which heap calculation needs to be made
@return Necessary size of heap which will store dict_index_stats_t of index */
static size_t dict_stats_index_stats_heap_size(const dict_index_t *index) {
  return sizeof(dict_index_stats_t) +
         dict_index_get_n_unique(index) *
             (sizeof(dict_index_stats_t::n_diff_key_vals[0]) +
              sizeof(dict_index_stats_t::n_sample_sizes[0]) +
              sizeof(dict_index_stats_t::n_non_null_key_vals[0]));
}

/** Calculates the size of heap to store all of the index statistics of the
table. It assumes that statistics are stored in dict_index_stats_t.
@param[in] table  table for which index statistics heap size needs to be
calculated
@return Necessary size of heap. */
static size_t dict_stats_index_stats_heap_size(const dict_table_t *table) {
  size_t heap_size = 0;

  for (auto index : table->indexes) {
    if (dict_stats_should_ignore_index(index)) {
      continue;
    }

    ut_ad(!dict_index_is_ibuf(index));

    heap_size += dict_stats_index_stats_heap_size(index);
  }

  return heap_size;
}

/** This function creates a dict_index_stats_t object and initializes
its members based on index. Outside caller should provide heap and assumes
ownership of the returned dict_index_stats_t object.
@param[in]  index   template index to create dict_index_stats_t from
@param[in]  heap    heap to be used by the dict_index_stats_t
*/
static dict_index_stats_t *dict_stats_create_index_stats(
    const dict_index_t *index, mem_heap_t *heap) {
  ut_a(heap);
  const size_t n_uniq = dict_index_get_n_unique(index);

  auto index_stats =
      (dict_index_stats_t *)mem_heap_alloc(heap, sizeof(dict_index_stats_t));
  index_stats->type = index->type;
  index_stats->n_uniq = n_uniq;

  auto alloc_n_uniq_elements = [&](auto &arr) {
    using Element = std::remove_reference_t<decltype(arr[0])>;
    arr = (Element *)mem_heap_alloc(heap, n_uniq * sizeof(Element));
  };
  alloc_n_uniq_elements(index_stats->n_diff_key_vals);
  alloc_n_uniq_elements(index_stats->n_sample_sizes);
  alloc_n_uniq_elements(index_stats->n_non_null_key_vals);

  return index_stats;
}

/** Copy index statistics from dict_index_stats_t to dict_index_t.
@param[in,out]  dst_idx         destination index
@param[in]      src_idx_stats   source index stats
*/
static void dict_stats_copy_index(dict_index_t *dst_idx,
                                  const dict_index_stats_t *src_idx_stats) {
  const size_t n_copy_el = dst_idx->n_uniq;
  ut_a_eq(dst_idx->n_uniq, src_idx_stats->n_uniq);

  memmove(dst_idx->stat_n_diff_key_vals, src_idx_stats->n_diff_key_vals,
          n_copy_el * sizeof(dst_idx->stat_n_diff_key_vals[0]));

#ifdef UNIV_DEBUG
  if (!(dst_idx->type & DICT_CLUSTERED)) {
    DEBUG_SYNC_C("inconsistent_secondary_stats_copy");
  }
#endif /* UNIV_DEBUG */

  memmove(dst_idx->stat_n_sample_sizes, src_idx_stats->n_sample_sizes,
          n_copy_el * sizeof(dst_idx->stat_n_sample_sizes[0]));

  memmove(dst_idx->stat_n_non_null_key_vals, src_idx_stats->n_non_null_key_vals,
          n_copy_el * sizeof(dst_idx->stat_n_non_null_key_vals[0]));

  dst_idx->stat_index_size = src_idx_stats->index_size;

  dst_idx->stat_n_leaf_pages = src_idx_stats->n_leaf_pages;

  dst_idx->assert_stats_initialized();
}

/** Calculates new estimates for index statistics. This function is
 relatively quick and is used to calculate transient statistics that
 are not saved on disk. This was the only way to calculate statistics
 before the Persistent Statistics feature was introduced. */
static void dict_stats_update_transient_for_index(
    dict_index_t *index,             /*!< in/out: index */
    dict_index_stats_t *index_stats) /*!< out: computed index statistics */
{
  ut_ad(index);
  ut_ad(index->table->stats_compute_mutex_created);
  ut_ad(mutex_own(index->table->stats_compute_mutex));

  if (srv_force_recovery >= SRV_FORCE_NO_TRX_UNDO &&
      (srv_force_recovery >= SRV_FORCE_NO_LOG_REDO || !index->is_clustered())) {
    /* If we have set a high innodb_force_recovery
    level, do not calculate statistics, as a badly
    corrupted index can cause a crash in it.
    Initialize some bogus index cardinality
    statistics, so that the data can be queried in
    various means, also via secondary indexes. */
    dict_stats_empty_index(index);
#if defined UNIV_DEBUG || defined UNIV_IBUF_DEBUG
  } else if (ibuf_debug && !index->is_clustered()) {
    dict_stats_empty_index(index);
#endif /* UNIV_DEBUG || UNIV_IBUF_DEBUG */
  } else {
    mtr_t mtr;
    ulint size;

    mtr_start(&mtr);
    dict_disable_redo_if_temporary(index->table, &mtr);

    mtr_s_lock(dict_index_get_lock(index), &mtr, UT_LOCATION_HERE);

    size = btr_get_size(index, BTR_TOTAL_SIZE, &mtr);

    DBUG_EXECUTE_IF("dict_stats_simulate_undefined_size",
                    { size = ULINT_UNDEFINED; });

    if (size != ULINT_UNDEFINED) {
      index_stats->index_size = size;

      size = btr_get_size(index, BTR_N_LEAF_PAGES, &mtr);
    }

    mtr_commit(&mtr);

    switch (size) {
      case ULINT_UNDEFINED:

        /* Size can be ULINT_UNDEFINED in two cases:
        1. In case of ongoing online ALTER. Statistics are rebuilt at the end of
        ha_innobase::commit_inplace_alter_table_impl(). So in this case we allow
        it to do the computation at the end of ALTER instead of blocking it.
        2. In case of full text indexes for which FIL_NULL is set to page
        pointer. Which is checked earlier and should not happen. */
        return;
      case 0:
        /* The root node of the tree is a leaf */
        size = 1;
    }

    index_stats->n_leaf_pages = size;

    /* We don't handle the return value since it will be false
    only when some thread is dropping the table and we don't
    have to empty the statistics of the to be dropped index */
    btr_estimate_number_of_different_key_vals(index, index_stats);
  }
}

/** Calculates new estimates for table and index statistics. This function
 is relatively quick and is used to calculate transient statistics that
 are not saved on disk.
 This was the only way to calculate statistics before the
 Persistent Statistics feature was introduced. */
static void dict_stats_update_transient(
    dict_table_t *table) /*!< in/out: table */
{
  dict_index_t *index;
  ulint sum_of_index_sizes = 0;

  /* Find out the sizes of the indexes and how many different values
  for the key they approximately have */

  index = table->first_index();

  if (dict_table_is_discarded(table)) {
    /* Nothing to do. */
    dict_stats_empty_table(table);
    return;
  } else if (index == nullptr) {
    /* Table definition is corrupt */

    ib::warn(ER_IB_MSG_221) << "Table " << table->name
                            << " has no indexes. Cannot calculate statistics.";
    dict_stats_empty_table(table);
    return;
  }

  /* Create the heap to store temporarily all stats of the table */
  size_t heap_size = dict_stats_index_stats_heap_size(table);
  Scoped_heap scoped_heap(heap_size, UT_LOCATION_HERE);

  dict_table_stats_compute_lock(table);

  /* Will store newly calculated stats for all indexes of the table. */
  std::vector<dict_index_stats_t *> stats{};

  for (; index != nullptr; index = index->next()) {
    ut_ad(!dict_index_is_ibuf(index));

    if (dict_stats_should_ignore_index(index)) {
      continue;
    }

#ifdef UNIV_DEBUG
    if (!(index->type & DICT_CLUSTERED)) {
      DEBUG_SYNC_C("dict_stats_analyze_index_empty_sk");
    }
#endif /* UNIV_DEBUG */

    dict_index_stats_t *statistics =
        dict_stats_create_index_stats(index, scoped_heap.get());
    dict_stats_empty_index_stats(statistics, index);
    dict_stats_update_transient_for_index(index, statistics);
    stats.push_back(statistics);

    sum_of_index_sizes += statistics->index_size;
  }

  dict_table_stats_lock(table, RW_X_LATCH);

  /* First copy table statistics. */
  index = table->first_index();
  dict_index_stats_t *statistics = stats.front();

  ulint n_unique = dict_index_get_n_unique(index);

  table->stat_n_rows = statistics->n_diff_key_vals[n_unique - 1];

  table->stat_clustered_index_size = statistics->index_size;

  table->stat_sum_of_other_index_sizes =
      sum_of_index_sizes - statistics->index_size;

  table->stats_last_recalc = std::chrono::steady_clock::now();

  table->stat_modified_counter = 0;

  table->stat_initialized = true;

  /* Now copy secondary index statistics. */
  auto stats_it = stats.begin();
  for (auto index : table->indexes) {
    if (index->type & DICT_FTS || dict_index_is_spatial(index)) {
      continue;
    }

    /* empty the statistics of corrupted, to be dropped and not committed */
    if (dict_stats_should_ignore_index(index)) {
      dict_stats_empty_index(index);
      continue;
    }

    dict_stats_copy_index(index, *stats_it);
    stats_it++;
  }

  dict_table_stats_unlock(table, RW_X_LATCH);

  dict_table_stats_compute_unlock(table);
}

/** Confirms long waiters for the index lock exist.
Wait time estimation is based on the last call of this function when not exist.
@param[in]      index           index
@param[in,out]  wait_start_time last known time index lock wasn't awaited.
Can be updated by this function if no waiter found now.
@return true if long waiters exist */
static bool dict_stats_index_long_waiters(
    dict_index_t *index,
    std::chrono::steady_clock::time_point &wait_start_time) {
  if (rw_lock_get_waiters(dict_index_get_lock(index))) {
    const auto diff = std::chrono::steady_clock::now() - wait_start_time;

    return diff > get_srv_fatal_semaphore_wait_threshold() / 2;
  } else {
    /* estimated long wait not started yet. updates wait_start_time. */
    wait_start_time = std::chrono::steady_clock::now();

    return false;
  }
}

/** @{ Pseudo code about the relation between the following functions

dict_stats_analyze_index()
  let N = N_SAMPLE_PAGES(index)
  try dict_stats_analyze_index_low(N)
  if timed out, try again with smaller N

dict_stats_analyze_index_low(N)
  for each n_prefix
    search for good enough level:
      dict_stats_analyze_index_level() // only called if level has <= N pages
        // full scan of the level in one mtr
        collect statistics about the given level
      if we are not satisfied with the level, search next lower level
    we have found a good enough level here
    dict_stats_analyze_index_for_n_prefix(that level, stats collected above)
      // full scan of the level in one mtr
      dive below some records and analyze the leaf page there:
      dict_stats_analyze_index_below_cur()
@} **/

/** Find the total number and the number of distinct keys on a given level in
 an index. Each of the 1..n_uniq prefixes are looked up and the results are
 saved in the array n_diff[0] .. n_diff[n_uniq - 1]. The total number of
 records on the level is saved in total_recs.
 Also, the index of the last record in each group of equal records is saved
 in n_diff_boundaries[0..n_uniq - 1], records indexing starts from the leftmost
 record on the level and continues cross pages boundaries, counting from 0.
@return false if aborted */
static bool dict_stats_analyze_index_level(
    dict_index_t *index,             /*!< in: index */
    ulint level,                     /*!< in: level */
    uint64_t *n_diff,                /*!< out: array for number of
                                        distinct keys for all prefixes */
    uint64_t *total_recs,            /*!< out: total number of records */
    uint64_t *total_pages,           /*!< out: total number of pages */
    boundaries_t *n_diff_boundaries, /*!< out: boundaries of the groups
                                   of distinct keys */
    std::chrono::steady_clock::time_point &wait_start_time,
    /*!< in/out: last known time index lock wasn't awaited. */
    mtr_t *mtr) /*!< in/out: mini-transaction */
{
  ulint n_uniq;
  mem_heap_t *heap;
  btr_pcur_t pcur;
  const page_t *page;
  const rec_t *rec;
  const rec_t *prev_rec;
  bool prev_rec_is_copied;
  byte *prev_rec_buf = nullptr;
  size_t prev_rec_buf_size = 0;
  ulint *rec_offsets;
  ulint *prev_rec_offsets;
  ulint i;
  bool success = true;

  DEBUG_PRINTF("    %s(table=%s, index=%s, level=%lu)\n", __func__,
               index->table->name, index->name, level);

  ut_ad(mtr_memo_contains(mtr, dict_index_get_lock(index), MTR_MEMO_SX_LOCK));

  n_uniq = dict_index_get_n_unique(index);

  /* elements in the n_diff array are 0..n_uniq-1 (inclusive) */
  memset(n_diff, 0x0, n_uniq * sizeof(n_diff[0]));

  /* Allocate space for the offsets header (the allocation size at
  offsets[0] and the REC_OFFS_HEADER_SIZE bytes), and n_fields + 1,
  so that this will never be less than the size calculated in
  rec_get_offsets(). */
  i = (REC_OFFS_HEADER_SIZE + 1 + 1) + index->n_fields;

  heap = mem_heap_create((2 * sizeof *rec_offsets) * i, UT_LOCATION_HERE);
  rec_offsets =
      static_cast<ulint *>(mem_heap_alloc(heap, i * sizeof *rec_offsets));
  prev_rec_offsets =
      static_cast<ulint *>(mem_heap_alloc(heap, i * sizeof *prev_rec_offsets));
  rec_offs_set_n_alloc(rec_offsets, i);
  rec_offs_set_n_alloc(prev_rec_offsets, i);

  /* reset the dynamic arrays n_diff_boundaries[0..n_uniq-1] */
  if (n_diff_boundaries != nullptr) {
    for (i = 0; i < n_uniq; i++) {
      n_diff_boundaries[i].erase(n_diff_boundaries[i].begin(),
                                 n_diff_boundaries[i].end());
    }
  }

  /* Position pcur on the leftmost record on the leftmost page
  on the desired level. */

  pcur.open_at_side(true, index, BTR_SEARCH_TREE | BTR_ALREADY_S_LATCHED, true,
                    level, mtr);
  pcur.move_to_next_on_page();

  page = pcur.get_page();

  /* The page must not be empty, except when
  it is the root page (and the whole index is empty). */
  ut_ad(pcur.is_on_user_rec() || page_is_leaf(page));
  ut_ad(pcur.get_rec() == page_rec_get_next_const(page_get_infimum_rec(page)));

  /* check that we are indeed on the desired level */
  ut_a(btr_page_get_level(page) == level);

  /* there should not be any pages on the left */
  ut_a(btr_page_get_prev(page, mtr) == FIL_NULL);

  /* check whether the first record on the leftmost page is marked
  as such, if we are on a non-leaf level */
  ut_a((level == 0) ==
       !(REC_INFO_MIN_REC_FLAG &
         rec_get_info_bits(pcur.get_rec(), page_is_comp(page))));

  prev_rec = nullptr;
  prev_rec_is_copied = false;

  /* We can release index->lock not to block others, when level==0.
  But the tree structure might be changed. */
  if (level == 0) {
    mtr_memo_release(mtr, dict_index_get_lock(index), MTR_MEMO_SX_LOCK);
  }

  /* no records by default */
  *total_recs = 0;

  *total_pages = 0;

  /* iterate over all user records on this level
  and compare each two adjacent ones, even the last on page
  X and the fist on page X+1 */
  for (; pcur.is_on_user_rec(); pcur.move_to_next_user_rec(mtr)) {
    bool rec_is_last_on_page;

    rec = pcur.get_rec();

    /* If rec and prev_rec are on different pages, then prev_rec
    must have been copied, because we hold latch only on the page
    where rec resides. */
    if (prev_rec != nullptr && page_align(rec) != page_align(prev_rec)) {
      ut_a(prev_rec_is_copied);
    }

    rec_is_last_on_page = page_rec_is_supremum(page_rec_get_next_const(rec));

    /* increment the pages counter at the end of each page */
    if (rec_is_last_on_page) {
      (*total_pages)++;

      if (level != 0 && (*total_pages) % 100 == 0 &&
          dict_stats_index_long_waiters(index, wait_start_time)) {
        /* long waiters exist. abort. */
        success = false;
        goto end;
      }
    }

    /* Skip delete-marked records on the leaf level. If we
    do not skip them, then ANALYZE quickly after DELETE
    could count them or not (purge may have already wiped
    them away) which brings non-determinism. We skip only
    leaf-level delete marks because delete marks on
    non-leaf level do not make sense. */

    if (level == 0 &&
        (srv_stats_include_delete_marked
             ? 0
             : rec_get_deleted_flag(rec, page_is_comp(pcur.get_page())))) {
      if (rec_is_last_on_page && !prev_rec_is_copied && prev_rec != nullptr) {
        /* copy prev_rec */

        prev_rec_offsets = rec_get_offsets(prev_rec, index, prev_rec_offsets,
                                           n_uniq, UT_LOCATION_HERE, &heap);

        prev_rec = rec_copy_prefix_to_buf(prev_rec, index,
                                          rec_offs_n_fields(prev_rec_offsets),
                                          &prev_rec_buf, &prev_rec_buf_size);

        prev_rec_is_copied = true;
      }

      continue;
    }
    rec_offsets = rec_get_offsets(rec, index, rec_offsets, n_uniq,
                                  UT_LOCATION_HERE, &heap);

    (*total_recs)++;

    if (prev_rec != nullptr) {
      ulint matched_fields;

      prev_rec_offsets = rec_get_offsets(prev_rec, index, prev_rec_offsets,
                                         n_uniq, UT_LOCATION_HERE, &heap);

      cmp_rec_rec_with_match(rec, prev_rec, rec_offsets, prev_rec_offsets,
                             index, false, false, &matched_fields);

      for (i = matched_fields; i < n_uniq; i++) {
        if (n_diff_boundaries != nullptr) {
          /* push the index of the previous
          record, that is - the last one from
          a group of equal keys */

          uint64_t idx;

          /* the index of the current record
          is total_recs - 1, the index of the
          previous record is total_recs - 2;
          we know that idx is not going to
          become negative here because if we
          are in this branch then there is a
          previous record and thus
          total_recs >= 2 */
          idx = *total_recs - 2;

          n_diff_boundaries[i].push_back(idx);
        }

        /* increment the number of different keys
        for n_prefix=i+1 (e.g. if i=0 then we increment
        for n_prefix=1 which is stored in n_diff[0]) */
        n_diff[i]++;
      }
    } else {
      /* this is the first non-delete marked record */
      for (i = 0; i < n_uniq; i++) {
        n_diff[i] = 1;
      }
    }

    if (rec_is_last_on_page) {
      /* end of a page has been reached */

      /* we need to copy the record instead of assigning
      like prev_rec = rec; because when we traverse the
      records on this level at some point we will jump from
      one page to the next and then rec and prev_rec will
      be on different pages and
      btr_pcur_t::move_to_next_user_rec() will release the
      latch on the page that prev_rec is on */
      prev_rec =
          rec_copy_prefix_to_buf(rec, index, rec_offs_n_fields(rec_offsets),
                                 &prev_rec_buf, &prev_rec_buf_size);
      prev_rec_is_copied = true;

    } else {
      /* still on the same page, the next call to
      btr_pcur_t::move_to_next_user_rec() will not jump
      on the next page, we can simply assign pointers
      instead of copying the records like above */

      prev_rec = rec;
      prev_rec_is_copied = false;
    }
  }

  /* if *total_pages is left untouched then the above loop was not
  entered at all and there is one page in the whole tree which is
  empty or the loop was entered but this is level 0, contains one page
  and all records are delete-marked */
  if (*total_pages == 0) {
    ut_ad(level == 0);
    ut_ad(*total_recs == 0);

    *total_pages = 1;
  }

  /* if there are records on this level and boundaries
  should be saved */
  if (*total_recs > 0 && n_diff_boundaries != nullptr) {
    /* remember the index of the last record on the level as the
    last one from the last group of equal keys; this holds for
    all possible prefixes */
    for (i = 0; i < n_uniq; i++) {
      uint64_t idx;

      idx = *total_recs - 1;

      n_diff_boundaries[i].push_back(idx);
    }
  }

  /* now in n_diff_boundaries[i] there are exactly n_diff[i] integers,
  for i=0..n_uniq-1 */

#ifdef UNIV_STATS_DEBUG
  for (i = 0; i < n_uniq; i++) {
    DEBUG_PRINTF("    %s(): total recs: " UINT64PF ", total pages: " UINT64PF
                 ", n_diff[%lu]: " UINT64PF "\n",
                 __func__, *total_recs, *total_pages, i, n_diff[i]);

#if 0
                if (n_diff_boundaries != NULL) {
                        uint64_t        j;

                        DEBUG_PRINTF("    %s(): boundaries[%lu]: ",
                                     __func__, i);

                        for (j = 0; j < n_diff[i]; j++) {
                                uint64_t        idx;

                                idx = n_diff_boundaries[i][j];

                                DEBUG_PRINTF(UINT64PF "=" UINT64PF ", ",
                                             j, idx);
                        }
                        DEBUG_PRINTF("\n");
                }
#endif
  }
#endif /* UNIV_STATS_DEBUG */

end:
  /* Release the latch on the last page, because that is not done by
  btr_pcur::close(). This function works also for non-leaf pages. */
  btr_leaf_page_release(pcur.get_block(), BTR_SEARCH_LEAF, mtr);

  pcur.close();
  ut::free(prev_rec_buf);
  mem_heap_free(heap);

  return success;
}

/** aux enum for controlling the behavior of dict_stats_scan_page() @{ */
enum page_scan_method_t {
  COUNT_ALL_NON_BORING_AND_SKIP_DEL_MARKED, /* scan all records on
                           the given page and count the number of
                           distinct ones, also ignore delete marked
                           records */
  QUIT_ON_FIRST_NON_BORING, /* quit when the first record that differs
                           from its right neighbor is found */
  COUNT_ALL_NON_BORING_INCLUDE_DEL_MARKED /* scan all records on
                           the given page and count the number of
                           distinct ones, include delete marked
                           records */
};
/** @} */

/** Scan a page, reading records from left to right and counting the number
of distinct records (looking only at the first n_prefix
columns) and the number of external pages pointed by records from this page.
If scan_method is QUIT_ON_FIRST_NON_BORING then the function
will return as soon as it finds a record that does not match its neighbor
to the right, which means that in the case of QUIT_ON_FIRST_NON_BORING the
returned n_diff can either be 0 (empty page), 1 (the whole page has all keys
equal) or 2 (the function found a non-boring record and returned).
@param[out]     out_rec                 record, or NULL
@param[out]     offsets1                rec_get_offsets() working space (must
be big enough)
@param[out]     offsets2                rec_get_offsets() working space (must
be big enough)
@param[in]      index                   index of the page
@param[in]      page                    the page to scan
@param[in]      n_prefix                look at the first n_prefix columns
@param[in]      scan_method             scan to the end of the page or not
@param[out]     n_diff                  number of distinct records encountered
@param[out]     n_external_pages        if this is non-NULL then it will be set
to the number of externally stored pages which were encountered
@return offsets1 or offsets2 (the offsets of *out_rec),
or NULL if the page is empty and does not contain user records. */
static inline ulint *dict_stats_scan_page(const rec_t **out_rec,
                                          ulint *offsets1, ulint *offsets2,
                                          const dict_index_t *index,
                                          const page_t *page, ulint n_prefix,
                                          page_scan_method_t scan_method,
                                          uint64_t *n_diff,
                                          uint64_t *n_external_pages) {
  ulint *offsets_rec = offsets1;
  ulint *offsets_next_rec = offsets2;
  const rec_t *rec;
  const rec_t *next_rec;
  /* A dummy heap, to be passed to rec_get_offsets().
  Because offsets1,offsets2 should be big enough,
  this memory heap should never be used. */
  mem_heap_t *heap = nullptr;
  const rec_t *(*get_next)(const rec_t *);

  if (scan_method == COUNT_ALL_NON_BORING_AND_SKIP_DEL_MARKED) {
    get_next = page_rec_get_next_non_del_marked;
  } else {
    get_next = page_rec_get_next_const;
  }

  const bool should_count_external_pages = n_external_pages != nullptr;

  if (should_count_external_pages) {
    *n_external_pages = 0;
  }

  rec = get_next(page_get_infimum_rec(page));

  if (page_rec_is_supremum(rec)) {
    /* the page is empty or contains only delete-marked records */
    *n_diff = 0;
    *out_rec = nullptr;
    return (nullptr);
  }

  offsets_rec = rec_get_offsets(rec, index, offsets_rec, ULINT_UNDEFINED,
                                UT_LOCATION_HERE, &heap);

  if (should_count_external_pages) {
    *n_external_pages +=
        lob::btr_rec_get_externally_stored_len(index, rec, offsets_rec);
  }

  next_rec = get_next(rec);

  *n_diff = 1;

  while (!page_rec_is_supremum(next_rec)) {
    ulint matched_fields;

    offsets_next_rec =
        rec_get_offsets(next_rec, index, offsets_next_rec, ULINT_UNDEFINED,
                        UT_LOCATION_HERE, &heap);

    /* check whether rec != next_rec when looking at
    the first n_prefix fields */
    cmp_rec_rec_with_match(rec, next_rec, offsets_rec, offsets_next_rec, index,
                           false, false, &matched_fields);

    if (matched_fields < n_prefix) {
      /* rec != next_rec, => rec is non-boring */

      (*n_diff)++;

      if (scan_method == QUIT_ON_FIRST_NON_BORING) {
        break;
      }
    }

    rec = next_rec;
    {
      /* Assign offsets_rec = offsets_next_rec
      so that offsets_rec matches with rec which
      was just assigned rec = next_rec above.
      Also need to point offsets_next_rec to the
      place where offsets_rec was pointing before
      because we have just 2 placeholders where
      data is actually stored:
      offsets1 and offsets2 and we
      are using them in circular fashion
      (offsets[_next]_rec are just pointers to
      those placeholders). */
      ulint *offsets_tmp;
      offsets_tmp = offsets_rec;
      offsets_rec = offsets_next_rec;
      offsets_next_rec = offsets_tmp;
    }

    if (should_count_external_pages) {
      *n_external_pages +=
          lob::btr_rec_get_externally_stored_len(index, rec, offsets_rec);
    }

    next_rec = get_next(next_rec);
  }

  /* offsets1,offsets2 should have been big enough */
  ut_a(heap == nullptr);
  *out_rec = rec;
  return (offsets_rec);
}

/** Dive below the current position of a cursor and calculate the number of
distinct records on the leaf page, when looking at the fist n_prefix
columns. Also calculate the number of external pages pointed by records
on the leaf page.
@param[in]      cur                     cursor
@param[in]      n_prefix                look at the first n_prefix columns
when comparing records
@param[out]     n_diff                  number of distinct records
@param[out]     n_external_pages        number of external pages
*/
static void dict_stats_analyze_index_below_cur(const btr_cur_t *cur,
                                               ulint n_prefix, uint64_t *n_diff,
                                               uint64_t *n_external_pages) {
  dict_index_t *index;
  buf_block_t *block;
  const page_t *page;
  mem_heap_t *heap;
  const rec_t *rec;
  ulint *offsets1;
  ulint *offsets2;
  ulint *offsets_rec;
  ulint size;
  mtr_t mtr;

  index = cur->index;

  /* Allocate offsets for the record and the node pointer, for
  node pointer records. In a secondary index, the node pointer
  record will consist of all index fields followed by a child
  page number.
  Allocate space for the offsets header (the allocation size at
  offsets[0] and the REC_OFFS_HEADER_SIZE bytes), and n_fields + 1,
  so that this will never be less than the size calculated in
  rec_get_offsets(). */
  size = (1 + REC_OFFS_HEADER_SIZE) + 1 + dict_index_get_n_fields(index);

  heap = mem_heap_create(size * (sizeof *offsets1 + sizeof *offsets2),
                         UT_LOCATION_HERE);

  offsets1 =
      static_cast<ulint *>(mem_heap_alloc(heap, size * sizeof *offsets1));

  offsets2 =
      static_cast<ulint *>(mem_heap_alloc(heap, size * sizeof *offsets2));

  rec_offs_set_n_alloc(offsets1, size);
  rec_offs_set_n_alloc(offsets2, size);

  rec = btr_cur_get_rec(cur);

  offsets_rec = rec_get_offsets(rec, index, offsets1, ULINT_UNDEFINED,
                                UT_LOCATION_HERE, &heap);

  page_id_t page_id(dict_index_get_space(index),
                    btr_node_ptr_get_child_page_no(rec, offsets_rec));
  const page_size_t page_size(dict_table_page_size(index->table));

  /* assume no external pages by default - in case we quit from this
  function without analyzing any leaf pages */
  *n_external_pages = 0;

  mtr_start(&mtr);

  /* descend to the leaf level on the B-tree */
  for (;;) {
    block = buf_page_get_gen(page_id, page_size, RW_S_LATCH,
                             nullptr /* no guessed block */, Page_fetch::NORMAL,
                             UT_LOCATION_HERE, &mtr);

    page = buf_block_get_frame(block);

    if (btr_page_get_level(page) == 0) {
      /* leaf level */
      break;
    }
    /* else */

    /* search for the first non-boring record on the page */
    offsets_rec =
        dict_stats_scan_page(&rec, offsets1, offsets2, index, page, n_prefix,
                             QUIT_ON_FIRST_NON_BORING, n_diff, nullptr);

    /* pages on level > 0 are not allowed to be empty */
    ut_a(offsets_rec != nullptr);
    /* if page is not empty (offsets_rec != NULL) then n_diff must
    be > 0, otherwise there is a bug in dict_stats_scan_page() */
    ut_a(*n_diff > 0);

    if (*n_diff == 1) {
      mtr_commit(&mtr);

      /* page has all keys equal and the end of the page
      was reached by dict_stats_scan_page(), no need to
      descend to the leaf level */
      mem_heap_free(heap);
      /* can't get an estimate for n_external_pages here
      because we do not dive to the leaf level, assume no
      external pages (*n_external_pages was assigned to 0
      above). */
      return;
    }
    /* else */

    /* when we instruct dict_stats_scan_page() to quit on the
    first non-boring record it finds, then the returned n_diff
    can either be 0 (empty page), 1 (page has all keys equal) or
    2 (non-boring record was found) */
    ut_a(*n_diff == 2);

    /* we have a non-boring record in rec, descend below it */

    page_id.set_page_no(btr_node_ptr_get_child_page_no(rec, offsets_rec));
  }

  /* make sure we got a leaf page as a result from the above loop */
  ut_ad(btr_page_get_level(page) == 0);

  /* scan the leaf page and find the number of distinct keys,
  when looking only at the first n_prefix columns; also estimate
  the number of externally stored pages pointed by records on this
  page */

  offsets_rec =
      dict_stats_scan_page(&rec, offsets1, offsets2, index, page, n_prefix,
                           srv_stats_include_delete_marked
                               ? COUNT_ALL_NON_BORING_INCLUDE_DEL_MARKED
                               : COUNT_ALL_NON_BORING_AND_SKIP_DEL_MARKED,
                           n_diff, n_external_pages);

#if 0
        DEBUG_PRINTF("      %s(): n_diff below page_no=%lu: " UINT64PF "\n",
                     __func__, page_no, n_diff);
#endif

  mtr_commit(&mtr);
  mem_heap_free(heap);
}

/** Input data that is used to calculate dict_index_t::stat_n_diff_key_vals[]
for each n-columns prefix (n from 1 to n_uniq). */
struct n_diff_data_t {
  /** Index of the level on which the descent through the btree
  stopped. level 0 is the leaf level. This is >= 1 because we
  avoid scanning the leaf level because it may contain too many
  pages and doing so is useless when combined with the random dives -
  if we are to scan the leaf level, this means a full scan and we can
  simply do that instead of fiddling with picking random records higher
  in the tree and to dive below them. At the start of the analyzing
  we may decide to do full scan of the leaf level, but then this
  structure is not used in that code path. */
  ulint level;

  /** Number of records on the level where the descend through the btree
  stopped. When we scan the btree from the root, we stop at some mid
  level, choose some records from it and dive below them towards a leaf
  page to analyze. */
  uint64_t n_recs_on_level;

  /** Number of different key values that were found on the mid level. */
  uint64_t n_diff_on_level;

  /** Number of leaf pages that are analyzed. This is also the same as
  the number of records that we pick from the mid level and dive below
  them. */
  uint64_t n_leaf_pages_to_analyze;

  /** Cumulative sum of the number of different key values that were
  found on all analyzed pages. */
  uint64_t n_diff_all_analyzed_pages;

  /** Cumulative sum of the number of external pages (stored outside of
  the btree but in the same file segment). */
  uint64_t n_external_pages_sum;
};

/** Estimate the number of different key values in an index when looking at
the first n_prefix columns. For a given level in an index select
n_diff_data->n_leaf_pages_to_analyze records from that level and dive below
them to the corresponding leaf pages, then scan those leaf pages and save the
sampling results in n_diff_data->n_diff_all_analyzed_pages.
@param[in]      index                   Index
@param[in]      n_prefix                Look at first 'n_prefix' columns when
comparing records
@param[in]      boundaries              A vector that contains
n_diff_data->n_diff_on_level integers each of which represents the index (on
level 'level', counting from left/smallest to right/biggest from 0) of the
last record from each group of distinct keys
@param[in,out]  n_diff_data             n_diff_all_analyzed_pages and
n_external_pages_sum in this structure will be set by this function. The
members level, n_diff_on_level and n_leaf_pages_to_analyze must be set by the
caller in advance - they are used by some calculations inside this function
@param[in,out]  wait_start_time         last known time index lock wasn't
awaited.
@param[in,out]  mtr                     Mini-transaction
@return false if aborted */
static bool dict_stats_analyze_index_for_n_prefix(
    dict_index_t *index, ulint n_prefix, const boundaries_t *boundaries,
    n_diff_data_t *n_diff_data,
    std::chrono::steady_clock::time_point &wait_start_time, mtr_t *mtr) {
  btr_pcur_t pcur;
  const page_t *page;
  uint64_t rec_idx;
  uint64_t i;

#if 0
        DEBUG_PRINTF("    %s(table=%s, index=%s, level=%lu, n_prefix=%lu,"
                     " n_diff_on_level=" UINT64PF ")\n",
                     __func__, index->table->name, index->name, level,
                     n_prefix, n_diff_data->n_diff_on_level);
#endif

  ut_ad(mtr_memo_contains(mtr, dict_index_get_lock(index), MTR_MEMO_SX_LOCK));

  /* Position pcur on the leftmost record on the leftmost page
  on the desired level. */

  pcur.open_at_side(true, index, BTR_SEARCH_TREE | BTR_ALREADY_S_LATCHED, true,
                    n_diff_data->level, mtr);
  pcur.move_to_next_on_page();

  page = pcur.get_page();

  const rec_t *first_rec = pcur.get_rec();

  /* We shouldn't be scanning the leaf level. The caller of this function
  should have stopped the descend on level 1 or higher. */
  ut_ad(n_diff_data->level > 0);
  ut_ad(!page_is_leaf(page));

  /* The page must not be empty, except when
  it is the root page (and the whole index is empty). */
  ut_ad(pcur.is_on_user_rec());
  ut_ad(first_rec == page_rec_get_next_const(page_get_infimum_rec(page)));

  /* check that we are indeed on the desired level */
  ut_a(btr_page_get_level(page) == n_diff_data->level);

  /* there should not be any pages on the left */
  ut_a(btr_page_get_prev(page, mtr) == FIL_NULL);

  /* check whether the first record on the leftmost page is marked
  as such; we are on a non-leaf level */
  ut_a(rec_get_info_bits(first_rec, page_is_comp(page)) &
       REC_INFO_MIN_REC_FLAG);

  const uint64_t last_idx_on_level =
      boundaries->at(static_cast<unsigned>(n_diff_data->n_diff_on_level - 1));

  rec_idx = 0;

  n_diff_data->n_diff_all_analyzed_pages = 0;
  n_diff_data->n_external_pages_sum = 0;

  for (i = 0; i < n_diff_data->n_leaf_pages_to_analyze; i++) {
    /* there are n_diff_on_level elements
    in 'boundaries' and we divide those elements
    into n_leaf_pages_to_analyze segments, for example:

    let n_diff_on_level=100, n_leaf_pages_to_analyze=4, then:
    segment i=0:  [0, 24]
    segment i=1: [25, 49]
    segment i=2: [50, 74]
    segment i=3: [75, 99] or

    let n_diff_on_level=1, n_leaf_pages_to_analyze=1, then:
    segment i=0: [0, 0] or

    let n_diff_on_level=2, n_leaf_pages_to_analyze=2, then:
    segment i=0: [0, 0]
    segment i=1: [1, 1] or

    let n_diff_on_level=13, n_leaf_pages_to_analyze=7, then:
    segment i=0:  [0,  0]
    segment i=1:  [1,  2]
    segment i=2:  [3,  4]
    segment i=3:  [5,  6]
    segment i=4:  [7,  8]
    segment i=5:  [9, 10]
    segment i=6: [11, 12]

    then we select a random record from each segment and dive
    below it */
    const uint64_t n_diff = n_diff_data->n_diff_on_level;
    const uint64_t n_pick = n_diff_data->n_leaf_pages_to_analyze;

    const uint64_t left = n_diff * i / n_pick;
    const uint64_t right = n_diff * (i + 1) / n_pick - 1;

    ut_a(left <= right);
    ut_a(right <= last_idx_on_level);

    const uint64_t rnd = ut::random_from_interval(left, right);

    const uint64_t dive_below_idx = boundaries->at(rnd);

#if 0
                DEBUG_PRINTF("    %s(): dive below record with index="
                             UINT64PF "\n", __func__, dive_below_idx);
#endif

    /* seek to the record with index dive_below_idx */
    while (rec_idx < dive_below_idx && pcur.is_on_user_rec()) {
      pcur.move_to_next_user_rec(mtr);
      rec_idx++;
    }

    /* if the level has finished before the record we are
    searching for, this means that the B-tree has changed in
    the meantime, quit our sampling and use whatever stats
    we have collected so far */
    if (rec_idx < dive_below_idx) {
      ut_ad(!pcur.is_on_user_rec());
      break;
    }

    /* it could be that the tree has changed in such a way that
    the record under dive_below_idx is the supremum record, in
    this case rec_idx == dive_below_idx and pcur is positioned
    on the supremum, we do not want to dive below it */
    if (!pcur.is_on_user_rec()) {
      break;
    }

    if ((i + 1) % 100 == 0 &&
        dict_stats_index_long_waiters(index, wait_start_time)) {
      /* long waiters exist. abort. */
      break;
    }

    ut_a(rec_idx == dive_below_idx);

    uint64_t n_diff_on_leaf_page;
    uint64_t n_external_pages;

    dict_stats_analyze_index_below_cur(pcur.get_btr_cur(), n_prefix,
                                       &n_diff_on_leaf_page, &n_external_pages);

    /* We adjust n_diff_on_leaf_page here to avoid counting
    one value twice - once as the last on some page and once
    as the first on another page. Consider the following example:
    Leaf level:
    page: (2,2,2,2,3,3)
    ... many pages like (3,3,3,3,3,3) ...
    page: (3,3,3,3,5,5)
    ... many pages like (5,5,5,5,5,5) ...
    page: (5,5,5,5,8,8)
    page: (8,8,8,8,9,9)
    our algo would (correctly) get an estimate that there are
    2 distinct records per page (average). Having 4 pages below
    non-boring records, it would (wrongly) estimate the number
    of distinct records to 8. */
    if (n_diff_on_leaf_page > 0) {
      n_diff_on_leaf_page--;
    }

    n_diff_data->n_diff_all_analyzed_pages += n_diff_on_leaf_page;

    n_diff_data->n_external_pages_sum += n_external_pages;
  }

  pcur.close();

  if (i < n_diff_data->n_leaf_pages_to_analyze) {
    /* return how much progressed */
    n_diff_data->n_leaf_pages_to_analyze = i;
    return false;
  }

  return true;
}

/** Set dict_index_stats_t::n_diff_key_vals[] and n_sample_sizes[].
@param[in]      n_diff_data     input data to use to derive the results
@param[in]      index           index associated with index_stats
@param[in,out]  index_stats     index_stats whose n_diff_key_vals[] to set */
static inline void dict_stats_index_set_n_diff(
    const n_diff_data_t *n_diff_data, dict_index_t *index,
    dict_index_stats_t *index_stats) {
  for (ulint n_prefix = index->n_uniq; n_prefix >= 1; n_prefix--) {
    /* n_diff_all_analyzed_pages can be 0 here if
    all the leaf pages sampled contained only
    delete-marked records. In this case we should assign
    0 to index_stats->n_diff_key_vals[n_prefix - 1], which
    the formula below does. */

    const n_diff_data_t *data = &n_diff_data[n_prefix - 1];

    ut_ad(data->n_leaf_pages_to_analyze > 0);
    ut_ad(data->n_recs_on_level > 0);

    uint64_t n_ordinary_leaf_pages;

    if (data->level == 1) {
      /* If we know the number of records on level 1, then
      this number is the same as the number of pages on
      level 0 (leaf). */
      n_ordinary_leaf_pages = data->n_recs_on_level;
    } else {
      /* If we analyzed D ordinary leaf pages and found E
      external pages in total linked from those D ordinary
      leaf pages, then this means that the ratio
      ordinary/external is D/E. Then the ratio ordinary/total
      is D / (D + E). Knowing that the total number of pages
      is T (including ordinary and external) then we estimate
      that the total number of ordinary leaf pages is
      T * D / (D + E). */
      n_ordinary_leaf_pages =
          index_stats->n_leaf_pages * data->n_leaf_pages_to_analyze /
          (data->n_leaf_pages_to_analyze + data->n_external_pages_sum);
    }

    /* See REF01 for an explanation of the algorithm */
    index_stats->n_diff_key_vals[n_prefix - 1] =
        n_ordinary_leaf_pages

        * data->n_diff_on_level / data->n_recs_on_level

        * data->n_diff_all_analyzed_pages / data->n_leaf_pages_to_analyze;

    index_stats->n_sample_sizes[n_prefix - 1] = data->n_leaf_pages_to_analyze;

    DEBUG_PRINTF(
        "    %s(): n_diff=" UINT64PF
        " for n_prefix=%lu"
        " (%lu"
        " * " UINT64PF " / " UINT64PF " * " UINT64PF " / " UINT64PF ")\n",
        __func__, index_stats->n_diff_key_vals[n_prefix - 1], n_prefix,
        index_stats->n_leaf_pages, data->n_diff_on_level, data->n_recs_on_level,
        data->n_diff_all_analyzed_pages, data->n_leaf_pages_to_analyze);
  }
}

/** Calculates new statistics for a given index and saves them to the
index_stats members n_diff_key_vals[], n_sample_sizes[],
index_size and n_leaf_pages, based on the specified n_sample_pages.

Allowing only successful updates also prevents abnormal stats
when the tree has changed beyond recognition or BUG#98132 Analyze table leads
to empty statistics during online rebuild DDL.

@param[in,out]  n_sample_pages number of leaf pages to
sample. and suggested next value to retry if aborted.
@param[in,out]  n_tickets number of tickets to retry without delay
@param[out]     no_delay retry without delay
@param[in,out]  simulate_tree_change simulate tree rebuild during stats
                calculation
@param[in]      index index to analyze.
@param[out]     index_stats calculated index statistics
@return false if aborted */
static bool dict_stats_analyze_index_low(uint64_t &n_sample_pages,
                                         uint64_t &n_tickets, bool &no_delay,
#ifdef UNIV_DEBUG
                                         bool &simulate_tree_change,
#endif /* UNIV_DEBUG */
                                         dict_index_t *index,
                                         dict_index_stats_t *index_stats) {
  ulint root_level;
  ulint level;
  bool level_is_analyzed;
  ulint n_uniq;
  ulint n_prefix;
  uint64_t total_recs;
  uint64_t total_pages;
  const uint64_t n_diff_required = n_sample_pages * 10;
  bool succeeded = true;
  mtr_t mtr;
  ulint size;

  ut_ad(index_stats);

  DBUG_TRACE;

  DBUG_PRINT("info", ("index: %s, online status: %d", index->name(),
                      dict_index_get_online_status(index)));

  /* Disable update statistic for Rtree */
  if (dict_index_is_spatial(index)) {
    return true;
  }

  DEBUG_PRINTF("  %s(index=%s)\n", __func__, index->name());

#ifdef UNIV_DEBUG
  if (!(index->type & DICT_CLUSTERED)) {
    DEBUG_SYNC_C("dict_stats_analyze_index_empty_sk");
  }
#endif /* UNIV_DEBUG */

  mtr_start(&mtr);

  mtr_s_lock(dict_index_get_lock(index), &mtr, UT_LOCATION_HERE);

  size = btr_get_size(index, BTR_TOTAL_SIZE, &mtr);

  DBUG_EXECUTE_IF("dict_stats_simulate_undefined_size",
                  { size = ULINT_UNDEFINED; });

  if (size != ULINT_UNDEFINED) {
    index_stats->index_size = size;
    size = btr_get_size(index, BTR_N_LEAF_PAGES, &mtr);
  }

  /* Release the X locks on the root page taken by btr_get_size() */
  mtr_commit(&mtr);

  switch (size) {
    case ULINT_UNDEFINED:

      DBUG_EXECUTE_IF("dict_stats_simulate_undefined_size",
                      DBUG_SET("-d,dict_stats_simulate_undefined_size"););

      /* Size can be ULINT_UNDEFINED in two cases:
      1. In case of ongoing online ALTER. Statistics are rebuilt at the end of
      ha_innobase::commit_inplace_alter_table_impl(). So in this case we allow
      it to do the computation at the end of ALTER instead of blocking it.
      2. In case of full text indexes for which FIL_NULL is set to page pointer.
      Which is checked earlier and should not happen. */
      return true;
    case 0:
      /* The root node of the tree is a leaf */
      size = 1;
  }

  index_stats->n_leaf_pages = size;

  mtr_start(&mtr);

  mtr_sx_lock(dict_index_get_lock(index), &mtr, UT_LOCATION_HERE);
  auto wait_start_time = std::chrono::steady_clock::now();

  root_level = btr_height_get(index, &mtr);

  n_uniq = dict_index_get_n_unique(index);

  DBUG_EXECUTE_IF("dict_stats_simulate_tree_change", { ut_a(root_level > 0); });

  /* If the tree has just one level (and one page) or if the user
  has requested to sample too many pages then do full scan.

  For each n-column prefix (for n=1..n_uniq) N_SAMPLE_PAGES(index)
  will be sampled, so in total N_SAMPLE_PAGES(index) * n_uniq leaf
  pages will be sampled. If that number is bigger than the total
  number of leaf pages then do full scan of the leaf level instead
  since it will be faster and will give better results.

  Also, we don't want to hold the dict_index_get_lock(index) SX_LOCK,
  (which is needed for scans on level>0) for too long, so we prefer a slower
  full scan without the SX_LOCK to a faster scan under SX_LOCK over 1e6+ pages.
  */
  if (root_level == 0 || n_sample_pages * n_uniq >
                             std::min<ulint>(index_stats->n_leaf_pages, 1e6)) {
    if (root_level == 0) {
      DEBUG_PRINTF(
          "  %s(): just one page,"
          " doing full scan\n",
          __func__);
    } else {
      DEBUG_PRINTF(
          "  %s(): too many pages requested for"
          " sampling, doing full scan\n",
          __func__);
    }

    /* do full scan of level 0; save results directly
    into the index */

    (void)dict_stats_analyze_index_level(
        index, 0 /* leaf level */, index_stats->n_diff_key_vals, &total_recs,
        &total_pages, nullptr /* boundaries not needed */, wait_start_time,
        &mtr);

    for (ulint i = 0; i < n_uniq; i++) {
      index_stats->n_sample_sizes[i] = total_pages;
    }

    mtr_commit(&mtr);

    index_stats->assert_initialized();

    return true;
  }

  /* For each level that is being scanned in the btree, this contains the
  number of different key values for all possible n-column prefixes. */
  uint64_t *n_diff_on_level = ut::new_arr_withkey<uint64_t>(
      ut::make_psi_memory_key(mem_key_dict_stats_n_diff_on_level),
      ut::Count{n_uniq});

  /* For each level that is being scanned in the btree, this contains the
  index of the last record from each group of equal records (when
  comparing only the first n columns, n=1..n_uniq). */
  boundaries_t *n_diff_boundaries = ut::new_arr_withkey<boundaries_t>(
      UT_NEW_THIS_FILE_PSI_KEY, ut::Count{n_uniq});

  /* For each n-column prefix this array contains the input data that is
  used to calculate dict_index_stats_t::n_diff_key_vals[]. */
  n_diff_data_t *n_diff_data = ut::new_arr_withkey<n_diff_data_t>(
      UT_NEW_THIS_FILE_PSI_KEY, ut::Count{n_uniq});

  /* total_recs is also used to estimate the number of pages on one
  level below, so at the start we have 1 page (the root) */
  total_recs = 1;

  /* Here we use the following optimization:
  If we find that level L is the first one (searching from the
  root) that contains at least D distinct keys when looking at
  the first n_prefix columns, then:
  if we look at the first n_prefix-1 columns then the first
  level that contains D distinct keys will be either L or a
  lower one.
  So if we find that the first level containing D distinct
  keys (on n_prefix columns) is L, we continue from L when
  searching for D distinct keys on n_prefix-1 columns. */
  level = root_level;
  level_is_analyzed = false;

  for (n_prefix = n_uniq; n_prefix >= 1; n_prefix--) {
    DEBUG_PRINTF(
        "  %s(): searching level with >=%llu"
        " distinct records, n_prefix=%lu\n",
        __func__, n_diff_required, n_prefix);

    /* Commit the mtr to release the tree SX lock to allow
    other threads to do some work too. */
    mtr_commit(&mtr);
    mtr_start(&mtr);
    mtr_sx_lock(dict_index_get_lock(index), &mtr, UT_LOCATION_HERE);
    wait_start_time = std::chrono::steady_clock::now();
    if (
#ifdef UNIV_DEBUG
        simulate_tree_change ||
#endif /* UNIV_DEBUG */
        root_level != btr_height_get(index, &mtr)) {
#ifdef UNIV_DEBUG
      simulate_tree_change = false;
#endif /* UNIV_DEBUG */
      /* Quit if the tree has changed beyond
      recognition here. The old stats from previous
      runs will remain in the values that we have
      not calculated yet. Initially when the index
      object is created the stats members are given
      some sensible values so leaving them untouched
      here even the first time will not cause us to
      read uninitialized memory. Stats will be
      recalculated in the next run.*/
      succeeded = false;
      break;
    }

    /* check whether we should pick the current level;
    we pick level 1 even if it does not have enough
    distinct records because we do not want to scan the
    leaf level because it may contain too many records */
    if (level_is_analyzed &&
        (n_diff_on_level[n_prefix - 1] >= n_diff_required || level == 1)) {
      goto found_level;
    }

    /* search for a level that contains enough distinct records */

    if (level_is_analyzed && level > 1) {
      /* if this does not hold we should be on
      "found_level" instead of here */
      ut_ad(n_diff_on_level[n_prefix - 1] < n_diff_required);

      level--;
      level_is_analyzed = false;
    }

    /* descend into the tree, searching for "good enough" level */
    for (;;) {
      /* make sure we do not scan the leaf level
      accidentally, it may contain too many pages */
      ut_ad(level > 0);

      /* scanning the same level twice is an optimization
      bug */
      ut_ad(!level_is_analyzed);

      /* Do not scan if this would read too many pages.
      Here we use the following fact:
      the number of pages on level L equals the number
      of records on level L+1, thus we deduce that the
      following call would scan total_recs pages, because
      total_recs is left from the previous iteration when
      we scanned one level upper or we have not scanned any
      levels yet in which case total_recs is 1. */
      if (total_recs > n_sample_pages) {
        /* if the above cond is true then we are
        not at the root level since on the root
        level total_recs == 1 (set before we
        enter the n-prefix loop) and cannot
        be > N_SAMPLE_PAGES(index) */
        ut_a(level != root_level);

        /* step one level back and be satisfied with
        whatever it contains */
        level++;
        level_is_analyzed = true;

        break;
      }

      const uint64_t prev_total_recs = total_recs;
      if (!dict_stats_analyze_index_level(
              index, level, n_diff_on_level, &total_recs, &total_pages,
              n_diff_boundaries, wait_start_time, &mtr)) {
        /* The other index->lock waiter is near to timeout.
        We should reduce requested pages for safety. */
        ut_ad(prev_total_recs <= n_sample_pages);
        n_sample_pages = prev_total_recs / 2;

        /* abort */
        succeeded = false;
        goto end;
      }

      level_is_analyzed = true;

      if (level == 1 || n_diff_on_level[n_prefix - 1] >= n_diff_required) {
        /* we have reached the last level we could scan
        or we found a good level with many distinct
        records */
        break;
      }

      level--;
      level_is_analyzed = false;
    }
  found_level:

    DEBUG_PRINTF("  %s(): found level %lu that has " UINT64PF
                 " distinct records for n_prefix=%lu\n",
                 __func__, level, n_diff_on_level[n_prefix - 1], n_prefix);
    /* here we are either on level 1 or the level that we are on
    contains >= N_DIFF_REQUIRED distinct keys or we did not scan
    deeper levels because they would contain too many pages */

    ut_ad(level > 0);

    ut_ad(level_is_analyzed);

    /* if any of these is 0 then there is exactly one page in the
    B-tree and it is empty and we should have done full scan and
    should not be here */
    ut_ad(total_recs > 0);
    ut_ad(n_diff_on_level[n_prefix - 1] > 0);

    ut_ad(n_sample_pages > 0);

    n_diff_data_t *data = &n_diff_data[n_prefix - 1];

    data->level = level;

    data->n_recs_on_level = total_recs;

    data->n_diff_on_level = n_diff_on_level[n_prefix - 1];

    data->n_leaf_pages_to_analyze =
        std::min(n_sample_pages, n_diff_on_level[n_prefix - 1]);

    /* pick some records from this level and dive below them for
    the given n_prefix */
    if (!dict_stats_analyze_index_for_n_prefix(index, n_prefix,
                                               &n_diff_boundaries[n_prefix - 1],
                                               data, wait_start_time, &mtr)) {
      /* The other index->lock waiter is near to timeout.
      We should reduce requested pages for safety. */
      ut_ad(data->n_leaf_pages_to_analyze <= n_sample_pages);
      n_sample_pages = data->n_leaf_pages_to_analyze / 2;

      /* abort */
      succeeded = false;
      goto end;
    }
  }

end:
  mtr_commit(&mtr);

  ut::delete_arr(n_diff_boundaries);

  ut::delete_arr(n_diff_on_level);

  /* n_prefix == 0 means that the above loop did not end up prematurely
  due to tree being changed and so n_diff_data[] is set up. */
  if (succeeded && n_prefix == 0) {
    dict_stats_index_set_n_diff(n_diff_data, index, index_stats);
  } else if (succeeded) {
    /* Change of tree height is rare. An immediate retrial
    should succeed. So consider it as a temporary failure. */
    if (n_tickets > 0) {
      n_tickets--;
      no_delay = true;
      succeeded = false;
    }
  }

  ut::delete_arr(n_diff_data);

  if (succeeded) {
    index_stats->assert_initialized();
  }

  return succeeded;
}

/** Calculates new statistics for a given index and saves them to the index
 members stat_n_diff_key_vals[], stat_n_sample_sizes[], stat_index_size and
 stat_n_leaf_pages. This function could be slow. */
static void dict_stats_analyze_index(
    dict_index_t *index,             /*!< in/out: index to analyze */
    dict_index_stats_t *index_stats) /*!< out: computed index statistics */
{
  ut_ad(index);
  ut_ad(index->table->stats_compute_mutex_created);
  ut_ad(mutex_own(index->table->stats_compute_mutex));

  uint64_t n_sample_pages = N_SAMPLE_PAGES(index);
  uint64_t n_no_delay_tickets = 1;
  bool no_delay = false;

#ifdef UNIV_DEBUG
  bool simulate_tree_change = false;
  DBUG_EXECUTE_IF("dict_stats_simulate_tree_change",
                  { simulate_tree_change = true; });
#endif /* UNIV_DEBUG */

  while (n_sample_pages > 0 && !dict_stats_analyze_index_low(
                                   n_sample_pages, n_no_delay_tickets, no_delay,
#ifdef UNIV_DEBUG
                                   simulate_tree_change,
#endif /* UNIV_DEBUG */
                                   index, index_stats)) {

    if (no_delay) {
      no_delay = false;
      continue;
    }

    /* aborted. retrying. */
    ib::warn(ER_IB_MSG_STATS_SAMPLING_TOO_LARGE)
        << "Detected too long lock waiting around " << index->table->name << "."
        << index->name
        << " stats_sample_pages. Retrying with the smaller value "
        << n_sample_pages << ".";

    /* Certain delay is needed for waiters to lock the index next. */
    std::this_thread::sleep_for(std::chrono::milliseconds(100));
  }
}

/** Calculates new estimates for table and index statistics. This function
 is relatively slow and is used to calculate persistent statistics that
 will be saved on disk.

 A local copy is used during analyze. Statistics for the given index will
 be overwritten by the copy at the end of this function. This is to prevent
 reading incorrect empty state.

 @param[in,out] table   table

 @return DB_SUCCESS or error code */
static dberr_t dict_stats_update_persistent(dict_table_t *table) {
  DEBUG_PRINTF("%s(table=%s)\n", __func__, table->name);

  /* analyze the clustered index first */
  auto index = table->first_index();

  if (index == nullptr || index->is_corrupted() ||
      (index->type | DICT_UNIQUE) != (DICT_CLUSTERED | DICT_UNIQUE)) {
    /* Table definition is corrupt */
    dict_stats_empty_table(table);

    return (DB_CORRUPTION);
  }

  dict_table_stats_compute_lock(table);

  ut_ad(!dict_index_is_ibuf(index));

  /* Create heap to store temporary local statistics of all indexes of the table
   */
  size_t heap_size = dict_stats_index_stats_heap_size(table);
  Scoped_heap scoped_heap(heap_size, UT_LOCATION_HERE);

  /* Will store newly calculated stats for all indexes of the table. */
  std::vector<dict_index_stats_t *> stats{};

  dict_index_stats_t *statistics =
      dict_stats_create_index_stats(index, scoped_heap.get());
  dict_stats_empty_index_stats(statistics, index);
  dict_stats_analyze_index(index, statistics);

  /* analyze other indexes from the table, if any */
  for (index = index->next(); index != nullptr; index = index->next()) {
    ut_ad(!dict_index_is_ibuf(index));

    if (dict_stats_should_ignore_index(index)) {
      continue;
    }

    if (!(table->stats_bg_flag & BG_STAT_SHOULD_QUIT)) {
      dict_index_stats_t *statistics =
          dict_stats_create_index_stats(index, scoped_heap.get());
      dict_stats_empty_index_stats(statistics, index);
      dict_stats_analyze_index(index, statistics);
      stats.push_back(statistics);
    }
  }

  CONDITIONAL_SYNC_POINT_TIMEOUT("completed_stats_computation", 5);

  /* Lock only for quick copying of tables and indexes statistics */
  dict_table_stats_lock(table, RW_X_LATCH);

  /* Copy table statistics */
  index = table->first_index();
  dict_stats_copy_index(index, statistics);

  ulint n_unique = dict_index_get_n_unique(index);

  table->stat_n_rows = index->stat_n_diff_key_vals[n_unique - 1];

  table->stat_clustered_index_size = index->stat_index_size;

  table->stat_sum_of_other_index_sizes = 0;

  DEBUG_SYNC_C("partial_stats_copy");

  /* copy statistics of the secondary indexes and update
   * stat_sum_of_other_index_sizes */
  auto stats_it = stats.begin();
  for (index = index->next(); index != nullptr; index = index->next()) {
    ut_ad(!dict_index_is_ibuf(index));

    if (index->type & DICT_FTS || dict_index_is_spatial(index)) {
      continue;
    }

    /* empty the statistics of corrupted, to be dropped and not committed */
    if (dict_stats_should_ignore_index(index)) {
      dict_stats_empty_index(index);
      continue;
    }

    if (!(table->stats_bg_flag & BG_STAT_SHOULD_QUIT)) {
      dict_stats_copy_index(index, *stats_it);
      stats_it++;
    }

    table->stat_sum_of_other_index_sizes += index->stat_index_size;
  }

  table->stats_last_recalc = std::chrono::steady_clock::now();

  table->stat_modified_counter = 0;

  table->stat_initialized = true;

  dict_stats_assert_initialized(table);

  dict_table_stats_unlock(table, RW_X_LATCH);

  dict_table_stats_compute_unlock(table);

  return (DB_SUCCESS);
}

#include "mysql_com.h"

/** Save an individual index's statistic into the persistent statistics
storage.
@param[in]      index                   index to be updated
@param[in]      last_update             timestamp of the stat
@param[in]      stat_name               name of the stat
@param[in]      stat_value              value of the stat
@param[in]      sample_size             n pages sampled or NULL
@param[in]      stat_description        description of the stat
@param[in,out]  trx                     in case of NULL the function will
allocate and free the trx object. If it is not NULL then it will be
rolled back only in the case of error, but not freed.
@param[in]      silent     if true, don't report error in the log file.
                           if false, report error in the log file.
@return DB_SUCCESS or error code */
static dberr_t dict_stats_save_index_stat(dict_index_t *index, lint last_update,
                                          const char *stat_name,
                                          uint64_t stat_value,
                                          uint64_t *sample_size,
                                          const char *stat_description,
                                          trx_t *trx, bool silent) {
  /* During upgrade, the indexes are loaded in dict_load_index_low and the
  clustered indexes are renamed as PRIMARY as MySQL understands only
  PRIMARY indexes. The following condition will be true only if such an index
  was renamed earlier during upgrade.
  During upgrade, the existing mysql.innodb_index_stats is backed up as
  mysql.innodb_index_stats_backup57 and new table mysql.innodb_index_stats
  is populated from the backup. After the upgrade, any entries missing
  in the new mysql.innodb_index_stats is populated here. Since, the clustered
  indexes were renamed to PRIMARY, a new entry in made into innodb_index_stats
  causing duplicate entries as the backup already has an entry for the
  corresponding clustered index. */
  if (strcmp(index->name, "PRIMARY") == 0 && index->type == DICT_CLUSTERED) {
    return DB_SUCCESS;
  }

  dberr_t ret;
  pars_info_t *pinfo;
  char db_utf8mb3[dict_name::MAX_DB_UTF8MB3_LEN];
  char table_utf8mb3[dict_name::MAX_TABLE_UTF8MB3_LEN];

  ut_ad(rw_lock_own(dict_operation_lock, RW_LOCK_X));

  dict_fs2utf8(index->table->name.m_name, db_utf8mb3, sizeof(db_utf8mb3),
               table_utf8mb3, sizeof(table_utf8mb3));

  pinfo = pars_info_create();
  pars_info_add_str_literal(pinfo, "database_name", db_utf8mb3);
  pars_info_add_str_literal(pinfo, "table_name", table_utf8mb3);
  pars_info_add_str_literal(pinfo, "index_name", index->name);
  UNIV_MEM_ASSERT_RW_ABORT(&last_update, 4);
  pars_info_add_int4_literal(pinfo, "last_update", last_update);
  UNIV_MEM_ASSERT_RW_ABORT(stat_name, strlen(stat_name));
  pars_info_add_str_literal(pinfo, "stat_name", stat_name);
  UNIV_MEM_ASSERT_RW_ABORT(&stat_value, 8);
  pars_info_add_ull_literal(pinfo, "stat_value", stat_value);
  if (sample_size != nullptr) {
    UNIV_MEM_ASSERT_RW_ABORT(sample_size, 8);
    pars_info_add_ull_literal(pinfo, "sample_size", *sample_size);
  } else {
    pars_info_add_literal(pinfo, "sample_size", nullptr, UNIV_SQL_NULL,
                          DATA_FIXBINARY, 0);
  }
  UNIV_MEM_ASSERT_RW_ABORT(stat_description, strlen(stat_description));
  pars_info_add_str_literal(pinfo, "stat_description", stat_description);

  ret = dict_stats_exec_sql(pinfo,
                            "PROCEDURE INDEX_STATS_SAVE () IS\n"
                            "BEGIN\n"

                            "DELETE FROM \"" INDEX_STATS_NAME
                            "\"\n"
                            "WHERE\n"
                            "database_name = :database_name AND\n"
                            "table_name = :table_name AND\n"
                            "index_name = :index_name AND\n"
                            "stat_name = :stat_name;\n"

                            "INSERT INTO \"" INDEX_STATS_NAME
                            "\"\n"
                            "VALUES\n"
                            "(\n"
                            ":database_name,\n"
                            ":table_name,\n"
                            ":index_name,\n"
                            ":last_update,\n"
                            ":stat_name,\n"
                            ":stat_value,\n"
                            ":sample_size,\n"
                            ":stat_description\n"
                            ");\n"
                            "END;",
                            trx);

  if (ret != DB_SUCCESS && !silent) {
    ib::error(ER_IB_MSG_222)
        << "Cannot save index statistics for table " << index->table->name
        << ", index " << index->name << ", stat name \"" << stat_name
        << "\": " << ut_strerr(ret);
  }

  return (ret);
}

/** Save the table's statistics into the persistent statistics storage.
@param[in]      table_orig      table whose stats to save
@param[in]      only_for_index  if this is non-NULL, then stats for indexes
that are not equal to it will not be saved, if NULL, then all indexes' stats
are saved
@param[in]      trx  Save stats using this transaction.  If nullptr, then
create a transaction and use that.
@param[in]  silent  if true, don't print any warnings to server log file.
@return DB_SUCCESS or error code */
static dberr_t dict_stats_save(dict_table_t *table_orig,
                               const index_id_t *only_for_index, trx_t *trx,
                               bool silent) {
  ut_ad(!dict_sys_mutex_own());
  log_free_check();
  pars_info_t *pinfo;
  dberr_t ret{};
  dict_table_t *table;
  char db_utf8mb3[dict_name::MAX_DB_UTF8MB3_LEN];
  char table_utf8mb3[dict_name::MAX_TABLE_UTF8MB3_LEN];
  const bool local_trx = (trx == nullptr);

  table = dict_stats_snapshot_create(table_orig);

  dict_fs2utf8(table->name.m_name, db_utf8mb3, sizeof(db_utf8mb3),
               table_utf8mb3, sizeof(table_utf8mb3));

  rw_lock_x_lock(dict_operation_lock, UT_LOCATION_HERE);

  /* MySQL's timestamp is 4 byte, so we use
  pars_info_add_int4_literal() which takes a lint arg, so "now" is
  lint */
  auto now = static_cast<uint32_t>(time(nullptr));

  pinfo = pars_info_create();

  pars_info_add_str_literal(pinfo, "database_name", db_utf8mb3);
  pars_info_add_str_literal(pinfo, "table_name", table_utf8mb3);
  pars_info_add_int4_literal(pinfo, "last_update", now);
  pars_info_add_ull_literal(pinfo, "n_rows", table->stat_n_rows);
  pars_info_add_ull_literal(pinfo, "clustered_index_size",
                            table->stat_clustered_index_size);
  pars_info_add_ull_literal(pinfo, "sum_of_other_index_sizes",
                            table->stat_sum_of_other_index_sizes);

  if (local_trx) {
    trx = trx_allocate_for_background();

    if (srv_read_only_mode) {
      trx_start_internal_read_only(trx, UT_LOCATION_HERE);
    } else {
      trx_start_internal(trx, UT_LOCATION_HERE);
    }
  }

  auto guard = create_scope_guard([&]() {
    if (local_trx) {
      if (ret == DB_SUCCESS) {
        trx_commit_for_mysql(trx);
      } else {
        trx_rollback_to_savepoint(trx, nullptr);
      }
      trx_free_for_background(trx);
    }
    rw_lock_x_unlock(dict_operation_lock);

    dict_stats_snapshot_free(table);
  });

  ret = dict_stats_exec_sql(pinfo,
                            "PROCEDURE TABLE_STATS_SAVE () IS\n"
                            "BEGIN\n"

                            "DELETE FROM \"" TABLE_STATS_NAME
                            "\"\n"
                            "WHERE\n"
                            "database_name = :database_name AND\n"
                            "table_name = :table_name;\n"

                            "INSERT INTO \"" TABLE_STATS_NAME
                            "\"\n"
                            "VALUES\n"
                            "(\n"
                            ":database_name,\n"
                            ":table_name,\n"
                            ":last_update,\n"
                            ":n_rows,\n"
                            ":clustered_index_size,\n"
                            ":sum_of_other_index_sizes\n"
                            ");\n"
                            "END;",
                            trx);

  if (ret != DB_SUCCESS) {
    if (!silent) {
      ib::error(ER_IB_MSG_223)
          << "Cannot save table statistics for table " << table->name << ": "
          << ut_strerr(ret) << " (" << __FILE_NAME__ << ":" << __LINE__ << ")";
    }
    return (ret);
  }

  dict_index_t *index;
  index_map_t indexes((ut_strcmp_functor()),
                      index_map_t_allocator(mem_key_dict_stats_index_map_t));

  /* Below we do all the modifications in innodb_index_stats in a single
  transaction for performance reasons. Modifying more than one row in a
  single transaction may deadlock with other transactions if they
  lock the rows in different order. Other transaction could be for
  example when we DROP a table and do
  DELETE FROM innodb_index_stats WHERE database_name = '...'
  AND table_name = '...'; which will affect more than one row. To
  prevent deadlocks we always lock the rows in the same order - the
  order of the PK, which is (database_name, table_name, index_name,
  stat_name). This is why below we sort the indexes by name and then
  for each index, do the mods ordered by stat_name. */

  for (index = table->first_index(); index != nullptr; index = index->next()) {
    indexes[index->name] = index;
  }

  index_map_t::const_iterator it;

  for (it = indexes.begin(); it != indexes.end(); ++it) {
    index = it->second;

    if (only_for_index != nullptr &&
        index->space != only_for_index->m_space_id &&
        index->id != only_for_index->m_index_id) {
      continue;
    }

    if (dict_stats_should_ignore_index(index)) {
      continue;
    }

    ut_ad(!dict_index_is_ibuf(index));

    for (ulint i = 0; i < index->n_uniq; i++) {
      char stat_name[16];
      char stat_description[1024];
      ulint j;

      snprintf(stat_name, sizeof(stat_name), "n_diff_pfx%02" ULINTPFS, i + 1);

      /* craft a string that contains the column names */
      snprintf(stat_description, sizeof(stat_description), "%s",
               index->fields[0].name());
      for (j = 1; j <= i; j++) {
        size_t len;

        len = strlen(stat_description);

        snprintf(stat_description + len, sizeof(stat_description) - len, ",%s",
                 index->fields[j].name());
      }

      ret = dict_stats_save_index_stat(
          index, now, stat_name, index->stat_n_diff_key_vals[i],
          &index->stat_n_sample_sizes[i], stat_description, trx, silent);

      if (ret != DB_SUCCESS) {
        return ret;
      }
    }

    ret = dict_stats_save_index_stat(index, now, "n_leaf_pages",
                                     index->stat_n_leaf_pages, nullptr,
                                     "Number of leaf pages "
                                     "in the index",
                                     trx, silent);
    if (ret != DB_SUCCESS) {
      return ret;
    }

    ret = dict_stats_save_index_stat(index, now, "size", index->stat_index_size,
                                     nullptr,
                                     "Number of pages "
                                     "in the index",
                                     trx, silent);
    if (ret != DB_SUCCESS) {
      return ret;
    }
  }

  return (ret);
}

/** Called for the row that is selected by
 SELECT ... FROM mysql.innodb_table_stats WHERE table='...'
 The second argument is a pointer to the table and the fetched stats are
 written to it.
 @return non-NULL dummy */
static bool dict_stats_fetch_table_stats_step(
    void *node_void,  /*!< in: select node */
    void *table_void) /*!< out: table */
{
  sel_node_t *node = (sel_node_t *)node_void;
  dict_table_t *table = (dict_table_t *)table_void;
  que_common_t *cnode;
  int i;

  /* this should loop exactly 3 times - for
  n_rows,clustered_index_size,sum_of_other_index_sizes */
  for (cnode = static_cast<que_common_t *>(node->select_list), i = 0;
       cnode != nullptr;
       cnode = static_cast<que_common_t *>(que_node_get_next(cnode)), i++) {
    const byte *data;
    dfield_t *dfield = que_node_get_val(cnode);
    dtype_t *type = dfield_get_type(dfield);
    ulint len = dfield_get_len(dfield);

    data = static_cast<const byte *>(dfield_get_data(dfield));

    switch (i) {
      case 0: /* mysql.innodb_table_stats.n_rows */

        ut_a(dtype_get_mtype(type) == DATA_INT);
        ut_a(len == 8);

        table->stat_n_rows = mach_read_from_8(data);

        break;

      case 1: /* mysql.innodb_table_stats.clustered_index_size */

        ut_a(dtype_get_mtype(type) == DATA_INT);
        ut_a(len == 8);

        table->stat_clustered_index_size = (ulint)mach_read_from_8(data);

        break;

      case 2: /* mysql.innodb_table_stats.sum_of_other_index_sizes */

        ut_a(dtype_get_mtype(type) == DATA_INT);
        ut_a(len == 8);

        table->stat_sum_of_other_index_sizes = (ulint)mach_read_from_8(data);

        break;

      default:

        /* someone changed SELECT
        n_rows,clustered_index_size,sum_of_other_index_sizes
        to select more columns from innodb_table_stats without
        adjusting here */
        ut_error;
    }
  }

  /* if i < 3 this means someone changed the
  SELECT n_rows,clustered_index_size,sum_of_other_index_sizes
  to select less columns from innodb_table_stats without adjusting here;
  if i > 3 we would have ut_error'ed earlier */
  ut_a(i == 3 /*n_rows,clustered_index_size,sum_of_other_index_sizes*/);

  /* XXX this is not used but returning non-NULL is necessary */
  return true;
}

/** Aux struct used to pass a table and a boolean to
dict_stats_fetch_index_stats_step(). */
struct index_fetch_t {
  dict_table_t *table;      /*!< table whose indexes are to be modified */
  bool stats_were_modified; /*!< will be set to true if at
               least one index stats were modified */
};

/** Called for the rows that are selected by
 SELECT ... FROM mysql.innodb_index_stats WHERE table='...'
 The second argument is a pointer to the table and the fetched stats are
 written to its indexes.
 Let a table has N indexes and each index has Ui unique columns for i=1..N,
 then mysql.innodb_index_stats will have SUM(Ui) i=1..N rows for that table.
 So this function will be called SUM(Ui) times where SUM(Ui) is of magnitude
 N*AVG(Ui). In each call it searches for the currently fetched index into
 table->indexes linearly, assuming this list is not sorted. Thus, overall,
 fetching all indexes' stats from mysql.innodb_index_stats is O(N^2) where N
 is the number of indexes.
 This can be improved if we sort table->indexes in a temporary area just once
 and then search in that sorted list. Then the complexity will be O(N*log(N)).
 We assume a table will not have more than 100 indexes, so we go with the
 simpler N^2 algorithm.
 @return non-NULL dummy */
static bool dict_stats_fetch_index_stats_step(
    void *node_void, /*!< in: select node */
    void *arg_void)  /*!< out: table + a flag that tells if we
                     modified anything */
{
  sel_node_t *node = (sel_node_t *)node_void;
  index_fetch_t *arg = (index_fetch_t *)arg_void;
  dict_table_t *table = arg->table;
  dict_index_t *index = nullptr;
  que_common_t *cnode;
  const char *stat_name = nullptr;
  ulint stat_name_len = ULINT_UNDEFINED;
  uint64_t stat_value = UINT64_UNDEFINED;
  uint64_t sample_size = UINT64_UNDEFINED;
  int i;

  /* this should loop exactly 4 times - for the columns that
  were selected: index_name,stat_name,stat_value,sample_size */
  for (cnode = static_cast<que_common_t *>(node->select_list), i = 0;
       cnode != nullptr;
       cnode = static_cast<que_common_t *>(que_node_get_next(cnode)), i++) {
    const byte *data;
    dfield_t *dfield = que_node_get_val(cnode);
    dtype_t *type = dfield_get_type(dfield);
    ulint len = dfield_get_len(dfield);

    data = static_cast<const byte *>(dfield_get_data(dfield));

    switch (i) {
      case 0: /* mysql.innodb_index_stats.index_name */

        ut_a(dtype_get_mtype(type) == DATA_VARMYSQL);

        /* search for index in table's indexes whose name
        matches data; the fetched index name is in data,
        has no terminating '\0' and has length len */
        for (index = table->first_index(); index != nullptr;
             index = index->next()) {
          if (index->is_committed() && strlen(index->name) == len &&
              memcmp(index->name, data, len) == 0) {
            /* the corresponding index was found */
            break;
          }
        }

        /* if index is NULL here this means that
        mysql.innodb_index_stats contains more rows than the
        number of indexes in the table; this is ok, we just
        return ignoring those extra rows; in other words
        dict_stats_fetch_index_stats_step() has been called
        for a row from index_stats with unknown index_name
        column */
        if (index == nullptr) {
          return true;
        }

        break;

      case 1: /* mysql.innodb_index_stats.stat_name */

        ut_a(dtype_get_mtype(type) == DATA_VARMYSQL);

        ut_a(index != nullptr);

        stat_name = (const char *)data;
        stat_name_len = len;

        break;

      case 2: /* mysql.innodb_index_stats.stat_value */

        ut_a(dtype_get_mtype(type) == DATA_INT);
        ut_a(len == 8);

        ut_a(index != nullptr);
        ut_a(stat_name != nullptr);
        ut_a(stat_name_len != ULINT_UNDEFINED);

        stat_value = mach_read_from_8(data);

        break;

      case 3: /* mysql.innodb_index_stats.sample_size */

        ut_a(dtype_get_mtype(type) == DATA_INT);
        ut_a(len == 8 || len == UNIV_SQL_NULL);

        ut_a(index != nullptr);
        ut_a(stat_name != nullptr);
        ut_a(stat_name_len != ULINT_UNDEFINED);
        ut_a(stat_value != UINT64_UNDEFINED);

        if (len == UNIV_SQL_NULL) {
          break;
        }
        /* else */

        sample_size = mach_read_from_8(data);

        break;

      default:

        /* someone changed
        SELECT index_name,stat_name,stat_value,sample_size
        to select more columns from innodb_index_stats without
        adjusting here */
        ut_error;
    }
  }

  /* if i < 4 this means someone changed the
  SELECT index_name,stat_name,stat_value,sample_size
  to select less columns from innodb_index_stats without adjusting here;
  if i > 4 we would have ut_error'ed earlier */
  ut_a(i == 4 /* index_name,stat_name,stat_value,sample_size */);

  ut_a(index != nullptr);
  ut_a(stat_name != nullptr);
  ut_a(stat_name_len != ULINT_UNDEFINED);
  ut_a(stat_value != UINT64_UNDEFINED);
  /* sample_size could be UINT64_UNDEFINED here, if it is NULL */

#define PFX "n_diff_pfx"
#define PFX_LEN 10

  if (stat_name_len == 4 /* strlen("size") */
      && native_strncasecmp("size", stat_name, stat_name_len) == 0) {
    index->stat_index_size = (ulint)stat_value;
    arg->stats_were_modified = true;
  } else if (stat_name_len == 12 /* strlen("n_leaf_pages") */
             && native_strncasecmp("n_leaf_pages", stat_name, stat_name_len) ==
                    0) {
    index->stat_n_leaf_pages = (ulint)stat_value;
    arg->stats_were_modified = true;
  } else if (stat_name_len > PFX_LEN /* e.g. stat_name=="n_diff_pfx01" */
             && native_strncasecmp(PFX, stat_name, PFX_LEN) == 0) {
    const char *num_ptr;
    unsigned long n_pfx;

    /* point num_ptr into "1" from "n_diff_pfx12..." */
    num_ptr = stat_name + PFX_LEN;

    /* stat_name should have exactly 2 chars appended to PFX
    and they should be digits */
    if (stat_name_len != PFX_LEN + 2 || num_ptr[0] < '0' || num_ptr[0] > '9' ||
        num_ptr[1] < '0' || num_ptr[1] > '9') {
      char db_utf8mb3[dict_name::MAX_DB_UTF8MB3_LEN];
      char table_utf8mb3[dict_name::MAX_TABLE_UTF8MB3_LEN];

      dict_fs2utf8(table->name.m_name, db_utf8mb3, sizeof(db_utf8mb3),
                   table_utf8mb3, sizeof(table_utf8mb3));

      ib::info out(ER_IB_MSG_1218);

      out << "Ignoring strange row from " << INDEX_STATS_NAME_PRINT
          << " WHERE"
             " database_name = '"
          << db_utf8mb3 << "' AND table_name = '" << table_utf8mb3
          << "' AND index_name = '" << index->name() << "' AND stat_name = '";
      out.write(stat_name, stat_name_len);
      out << "'; because stat_name is malformed";
      return true;
    }
    /* else */

    /* extract 12 from "n_diff_pfx12..." into n_pfx
    note that stat_name does not have a terminating '\0' */
    n_pfx = (num_ptr[0] - '0') * 10 + (num_ptr[1] - '0');

    ulint n_uniq = index->n_uniq;

    if (n_pfx == 0 || n_pfx > n_uniq) {
      char db_utf8mb3[dict_name::MAX_DB_UTF8MB3_LEN];
      char table_utf8mb3[dict_name::MAX_TABLE_UTF8MB3_LEN];

      dict_fs2utf8(table->name.m_name, db_utf8mb3, sizeof(db_utf8mb3),
                   table_utf8mb3, sizeof(table_utf8mb3));

      ib::info out(ER_IB_MSG_1219);

      out << "Ignoring strange row from " << INDEX_STATS_NAME_PRINT
          << " WHERE"
             " database_name = '"
          << db_utf8mb3 << "' AND table_name = '" << table_utf8mb3
          << "' AND index_name = '" << index->name() << "' AND stat_name = '";
      out.write(stat_name, stat_name_len);
      out << "'; because stat_name is out of range, the index"
             " has "
          << n_uniq << " unique columns";

      return true;
    }
    /* else */

    index->stat_n_diff_key_vals[n_pfx - 1] = stat_value;

    if (sample_size != UINT64_UNDEFINED) {
      index->stat_n_sample_sizes[n_pfx - 1] = sample_size;
    } else {
      /* hmm, strange... the user must have UPDATEd the
      table manually and SET sample_size = NULL */
      index->stat_n_sample_sizes[n_pfx - 1] = 0;
    }

    index->stat_n_non_null_key_vals[n_pfx - 1] = 0;

    arg->stats_were_modified = true;
  } else {
    /* silently ignore rows with unknown stat_name, the
    user may have developed her own stats */
  }

  /* XXX this is not used but returning non-NULL is necessary */
  return true;
}

/** Read table's statistics from the persistent statistics storage.
 @return DB_SUCCESS or error code */
static dberr_t dict_stats_fetch_from_ps(
    dict_table_t *table) /*!< in/out: table */
{
  index_fetch_t index_fetch_arg;
  trx_t *trx;
  pars_info_t *pinfo;
  dberr_t ret;
  char db_utf8mb3[dict_name::MAX_DB_UTF8MB3_LEN];
  char table_utf8mb3[dict_name::MAX_TABLE_UTF8MB3_LEN];

  ut_ad(!dict_sys_mutex_own());

  /* Initialize all stats to dummy values before fetching because if
  the persistent storage contains incomplete stats (e.g. missing stats
  for some index) then we would end up with (partially) uninitialized
  stats. */
  dict_stats_empty_table(table);

  trx = trx_allocate_for_background();

  /* Use 'read-uncommitted' so that the SELECTs we execute
  do not get blocked in case some user has locked the rows we
  are SELECTing */

  trx->isolation_level = TRX_ISO_READ_UNCOMMITTED;

  if (srv_read_only_mode) {
    trx_start_internal_read_only(trx, UT_LOCATION_HERE);
  } else {
    trx_start_internal(trx, UT_LOCATION_HERE);
  }

  dict_fs2utf8(table->name.m_name, db_utf8mb3, sizeof(db_utf8mb3),
               table_utf8mb3, sizeof(table_utf8mb3));

  pinfo = pars_info_create();

  pars_info_add_str_literal(pinfo, "database_name", db_utf8mb3);

  pars_info_add_str_literal(pinfo, "table_name", table_utf8mb3);

  pars_info_bind_function(pinfo, "fetch_table_stats_step",
                          dict_stats_fetch_table_stats_step, table);

  index_fetch_arg.table = table;
  index_fetch_arg.stats_were_modified = false;
  pars_info_bind_function(pinfo, "fetch_index_stats_step",
                          dict_stats_fetch_index_stats_step, &index_fetch_arg);

  ret = que_eval_sql(pinfo,
                     "PROCEDURE FETCH_STATS () IS\n"
                     "found INT;\n"
                     "DECLARE FUNCTION fetch_table_stats_step;\n"
                     "DECLARE FUNCTION fetch_index_stats_step;\n"
                     "DECLARE CURSOR table_stats_cur IS\n"
                     "  SELECT\n"
                     /* if you change the selected fields, be
                     sure to adjust
                     dict_stats_fetch_table_stats_step() */
                     "  n_rows,\n"
                     "  clustered_index_size,\n"
                     "  sum_of_other_index_sizes\n"
                     "  FROM \"" TABLE_STATS_NAME
                     "\"\n"
                     "  WHERE\n"
                     "  database_name = :database_name AND\n"
                     "  table_name = :table_name;\n"
                     "DECLARE CURSOR index_stats_cur IS\n"
                     "  SELECT\n"
                     /* if you change the selected fields, be
                     sure to adjust
                     dict_stats_fetch_index_stats_step() */
                     "  index_name,\n"
                     "  stat_name,\n"
                     "  stat_value,\n"
                     "  sample_size\n"
                     "  FROM \"" INDEX_STATS_NAME
                     "\"\n"
                     "  WHERE\n"
                     "  database_name = :database_name AND\n"
                     "  table_name = :table_name;\n"

                     "BEGIN\n"

                     "OPEN table_stats_cur;\n"
                     "FETCH table_stats_cur INTO\n"
                     "  fetch_table_stats_step();\n"
                     "IF (SQL % NOTFOUND) THEN\n"
                     "  CLOSE table_stats_cur;\n"
                     "  RETURN;\n"
                     "END IF;\n"
                     "CLOSE table_stats_cur;\n"

                     "OPEN index_stats_cur;\n"
                     "found := 1;\n"
                     "WHILE found = 1 LOOP\n"
                     "  FETCH index_stats_cur INTO\n"
                     "    fetch_index_stats_step();\n"
                     "  IF (SQL % NOTFOUND) THEN\n"
                     "    found := 0;\n"
                     "  END IF;\n"
                     "END LOOP;\n"
                     "CLOSE index_stats_cur;\n"

                     "END;",
                     trx);
  /* pinfo is freed by que_eval_sql() */

  trx_commit_for_mysql(trx);

  trx_free_for_background(trx);

  if (!index_fetch_arg.stats_were_modified) {
    return (DB_STATS_DO_NOT_EXIST);
  }

  return (ret);
}

/** Fetches or calculates new estimates for index statistics. */
void dict_stats_update_for_index(dict_index_t *index) /*!< in/out: index */
{
  DBUG_TRACE;

  ut_ad(!dict_sys_mutex_own());

  /* Heap to store index stats */
  const size_t heap_size = dict_stats_index_stats_heap_size(index);
  Scoped_heap scoped_heap(heap_size, UT_LOCATION_HERE);

  dict_table_stats_compute_lock(index->table);

  dict_index_stats_t *statistics =
      dict_stats_create_index_stats(index, scoped_heap.get());
  dict_stats_empty_index_stats(statistics, index);

  if (dict_stats_is_persistent_enabled(index->table)) {
    dict_stats_analyze_index(index, statistics);
    dict_table_stats_lock(index->table, RW_X_LATCH);
    dict_stats_copy_index(index, statistics);
    dict_table_stats_unlock(index->table, RW_X_LATCH);
    dict_table_stats_compute_unlock(index->table);
    index_id_t index_id(index->space, index->id);
    const bool silent = false;
    dict_stats_save(index->table, &index_id, nullptr, silent);
    return;
  }

  dict_stats_update_transient_for_index(index, statistics);
  dict_table_stats_lock(index->table, RW_X_LATCH);
  dict_stats_copy_index(index, statistics);
  dict_table_stats_unlock(index->table, RW_X_LATCH);
  dict_table_stats_compute_unlock(index->table);
}

dberr_t dict_stats_update_retry(dict_table_t *table,
                                dict_stats_upd_option_t stats_upd_option,
                                size_t max_retries) {
  dberr_t err{DB_SUCCESS};

  for (size_t i = max_retries; i > 0; --i) {
    const bool silent = (i == 1) ? false : true;
    err = dict_stats_update(table, stats_upd_option, nullptr, silent);

    if (err == DB_LOCK_WAIT_TIMEOUT) {
      std::this_thread::sleep_for(std::chrono::milliseconds{100});
      continue;
    }

    break;
  }

  return err;
}

dberr_t dict_stats_update(dict_table_t *table,
                          dict_stats_upd_option_t stats_upd_option, trx_t *trx,
                          bool silent) {
  ut_ad(!dict_sys_mutex_own());

  if (table->ibd_file_missing) {
    if (!dict_table_is_discarded(table)) {
      ib::warn(ER_IB_MSG_224)
          << "Cannot calculate statistics for table " << table->name
          << " because the .ibd file is missing. " << TROUBLESHOOTING_MSG;
    }
    dict_stats_empty_table(table);
    return (DB_TABLESPACE_DELETED);
  } else if (srv_force_recovery >= SRV_FORCE_NO_IBUF_MERGE) {
    /* If we have set a high innodb_force_recovery level, do
    not calculate statistics, as a badly corrupted index can
    cause a crash in it. */
    dict_stats_empty_table(table);
    return (DB_SUCCESS);
  }

  switch (stats_upd_option) {
    dberr_t err;

    case DICT_STATS_RECALC_PERSISTENT:

      if (srv_read_only_mode) {
        break;
      }

      /* wakes the last purge batch for exact recalculation */
      if (trx_sys->rseg_history_len.load() > 0) {
        srv_wake_purge_thread_if_not_active();
      }

      /* Persistent recalculation requested, called from
      1) ANALYZE TABLE, or
      2) the auto recalculation background thread, or
      3) open table if stats do not exist on disk and auto recalc
         is enabled */

      /* InnoDB internal tables (e.g. SYS_TABLES) cannot have
      persistent stats enabled */
      ut_a(strchr(table->name.m_name, '/') != nullptr);

      err = dict_stats_update_persistent(table);

      if (err != DB_SUCCESS) {
        return (err);
      }

      return (dict_stats_save(table, nullptr, trx, silent));

    case DICT_STATS_RECALC_TRANSIENT:
      break;

    case DICT_STATS_EMPTY_TABLE:

      dict_stats_empty_table(table);

      /* If table is using persistent stats,
      then save the stats on disk */

      if (dict_stats_is_persistent_enabled(table)) {
        return (dict_stats_save(table, nullptr, trx, silent));
      }

      return (DB_SUCCESS);

    case DICT_STATS_FETCH_ONLY_IF_NOT_IN_MEMORY:

      /* fetch requested, either fetch from persistent statistics
      storage or use the old method */

      if (table->stat_initialized) {
        return (DB_SUCCESS);
      }

      /* InnoDB internal tables (e.g. SYS_TABLES) cannot have
      persistent stats enabled */
      ut_a(strchr(table->name.m_name, '/') != nullptr);

      /* Create a dummy table object with the same name and
      indexes, suitable for fetching the stats into it. */
      dict_table_t *t = dict_stats_table_clone_create(table);

      err = dict_stats_fetch_from_ps(t);

      t->stats_last_recalc = table->stats_last_recalc;
      t->stat_modified_counter = 0;

      switch (err) {
        case DB_SUCCESS:

          dict_table_stats_lock(table, RW_X_LATCH);

          dict_stats_copy(table, t);

          dict_stats_assert_initialized(table);

          dict_table_stats_unlock(table, RW_X_LATCH);

          dict_stats_table_clone_free(t);

          return (DB_SUCCESS);
        case DB_STATS_DO_NOT_EXIST:

          dict_stats_table_clone_free(t);

          if (srv_read_only_mode) {
            break;
          }

          if (dict_stats_auto_recalc_is_enabled(table)) {
            return (dict_stats_update(table, DICT_STATS_RECALC_PERSISTENT));
          }

          ib::info(ER_IB_MSG_225)
              << "Trying to use table " << table->name
              << " which has persistent statistics enabled,"
                 " but auto recalculation turned off and the"
                 " statistics do not exist in " TABLE_STATS_NAME_PRINT
                 " and " INDEX_STATS_NAME_PRINT
                 ". Please either run \"ANALYZE TABLE "
              << table->name
              << ";\" manually or enable the"
                 " auto recalculation with \"ALTER TABLE "
              << table->name
              << " STATS_AUTO_RECALC=1;\"."
                 " InnoDB will now use transient statistics for "
              << table->name << ".";

          break;
        default:

          dict_stats_table_clone_free(t);

          ib::error(ER_IB_MSG_226)
              << "Error fetching persistent statistics"
                 " for table "
              << table->name
              << " from " TABLE_STATS_NAME_PRINT " and " INDEX_STATS_NAME_PRINT
                 ": "
              << ut_strerr(err) << ". Using transient stats method instead.";

          break;
      }
      /* no "default:" in order to produce a compilation warning
      about unhandled enumeration value */
  }

  dict_stats_update_transient(table);

  return (DB_SUCCESS);
}

/** Removes the information for a particular index's stats from the persistent
 storage if it exists and if there is data stored for this index.
 This function creates its own trx and commits it.
 A note from Marko why we cannot edit user and sys_* tables in one trx:
 marko: The problem is that ibuf merges should be disabled while we are
 rolling back dict transactions.
 marko: If ibuf merges are not disabled, we need to scan the *.ibd files.
 But we shouldn't open *.ibd files before we have rolled back dict
 transactions and opened the SYS_* records for the *.ibd files.
 @return DB_SUCCESS or error code */
dberr_t dict_stats_drop_index(
    const char *db_and_table, /*!< in: db and table, e.g. 'db/table' */
    const char *iname,        /*!< in: index name */
    char *errstr,             /*!< out: error message if != DB_SUCCESS
                              is returned */
    ulint errstr_sz)          /*!< in: size of the errstr buffer */
{
  char db_utf8mb3[dict_name::MAX_DB_UTF8MB3_LEN];
  char table_utf8mb3[dict_name::MAX_TABLE_UTF8MB3_LEN];
  pars_info_t *pinfo;
  dberr_t ret;

  ut_ad(!dict_sys_mutex_own());

  /* skip indexes whose table names do not contain a database name
  e.g. if we are dropping an index from SYS_TABLES */
  if (strchr(db_and_table, '/') == nullptr) {
    return (DB_SUCCESS);
  }

  dict_fs2utf8(db_and_table, db_utf8mb3, sizeof(db_utf8mb3), table_utf8mb3,
               sizeof(table_utf8mb3));

  pinfo = pars_info_create();

  pars_info_add_str_literal(pinfo, "database_name", db_utf8mb3);

  pars_info_add_str_literal(pinfo, "table_name", table_utf8mb3);

  pars_info_add_str_literal(pinfo, "index_name", iname);

  rw_lock_x_lock(dict_operation_lock, UT_LOCATION_HERE);

  ret = dict_stats_exec_sql(pinfo,
                            "PROCEDURE DROP_INDEX_STATS () IS\n"
                            "BEGIN\n"
                            "DELETE FROM \"" INDEX_STATS_NAME
                            "\" WHERE\n"
                            "database_name = :database_name AND\n"
                            "table_name = :table_name AND\n"
                            "index_name = :index_name;\n"
                            "END;\n",
                            nullptr);

  rw_lock_x_unlock(dict_operation_lock);

  if (ret == DB_STATS_DO_NOT_EXIST) {
    ret = DB_SUCCESS;
  }

  if (ret != DB_SUCCESS) {
    snprintf(
        errstr, errstr_sz,
        "Unable to delete statistics for index %s"
        " from %s%s: %s. They can be deleted later using"
        " DELETE FROM %s WHERE"
        " database_name = '%s' AND"
        " table_name = '%s' AND"
        " index_name = '%s';",
        iname, INDEX_STATS_NAME_PRINT,
        (ret == DB_LOCK_WAIT_TIMEOUT ? " because the rows are locked" : ""),
        ut_strerr(ret), INDEX_STATS_NAME_PRINT, db_utf8mb3, table_utf8mb3,
        iname);

    ut_print_timestamp(stderr);
    fprintf(stderr, " InnoDB: %s\n", errstr);
  }

  return (ret);
}

/** Executes
 DELETE FROM mysql.innodb_table_stats
 WHERE database_name = '...' AND table_name = '...';
 Creates its own transaction and commits it.
 @return DB_SUCCESS or error code */
static inline dberr_t dict_stats_delete_from_table_stats(
    const char *database_name, /*!< in: database name, e.g. 'db' */
    const char *table_name)    /*!< in: table name, e.g. 'table' */
{
  pars_info_t *pinfo;
  dberr_t ret;

  ut_ad(rw_lock_own(dict_operation_lock, RW_LOCK_X));

  pinfo = pars_info_create();

  pars_info_add_str_literal(pinfo, "database_name", database_name);
  pars_info_add_str_literal(pinfo, "table_name", table_name);

  ret = dict_stats_exec_sql(pinfo,
                            "PROCEDURE DELETE_FROM_TABLE_STATS () IS\n"
                            "BEGIN\n"
                            "DELETE FROM \"" TABLE_STATS_NAME
                            "\" WHERE\n"
                            "database_name = :database_name AND\n"
                            "table_name = :table_name;\n"
                            "END;\n",
                            nullptr);

  return (ret);
}

/** Executes
 DELETE FROM mysql.innodb_index_stats
 WHERE database_name = '...' AND table_name = '...';
 Creates its own transaction and commits it.
 @return DB_SUCCESS or error code */
static inline dberr_t dict_stats_delete_from_index_stats(
    const char *database_name, /*!< in: database name, e.g. 'db' */
    const char *table_name)    /*!< in: table name, e.g. 'table' */
{
  pars_info_t *pinfo;
  dberr_t ret;

  ut_ad(rw_lock_own(dict_operation_lock, RW_LOCK_X));

  pinfo = pars_info_create();

  pars_info_add_str_literal(pinfo, "database_name", database_name);
  pars_info_add_str_literal(pinfo, "table_name", table_name);

  ret = dict_stats_exec_sql(pinfo,
                            "PROCEDURE DELETE_FROM_INDEX_STATS () IS\n"
                            "BEGIN\n"
                            "DELETE FROM \"" INDEX_STATS_NAME
                            "\" WHERE\n"
                            "database_name = :database_name AND\n"
                            "table_name = :table_name;\n"
                            "END;\n",
                            nullptr);

  return (ret);
}

/** Removes the statistics for a table and all of its indexes from the
 persistent statistics storage if it exists and if there is data stored for
 the table. This function creates its own transaction and commits it.
 @return DB_SUCCESS or error code */
dberr_t dict_stats_drop_table(
    const char *db_and_table, /*!< in: db and table, e.g. 'db/table' */
    char *errstr,             /*!< out: error message
                              if != DB_SUCCESS is returned */
    ulint errstr_sz)          /*!< in: size of errstr buffer */
{
  char db_utf8mb3[dict_name::MAX_DB_UTF8MB3_LEN];
  char table_utf8mb3[dict_name::MAX_TABLE_UTF8MB3_LEN];
  dberr_t ret;

  ut_ad(rw_lock_own(dict_operation_lock, RW_LOCK_X));
  /* WL#9536 TODO: Once caller don't hold dict sys mutex, clean
  this and following(exit&enter) up */
  ut_ad(dict_sys_mutex_own());

  /* skip tables that do not contain a database name
  e.g. if we are dropping SYS_TABLES */
  if (strchr(db_and_table, '/') == nullptr) {
    return (DB_SUCCESS);
  }

  /* skip innodb_table_stats and innodb_index_stats themselves */
  if (strcmp(db_and_table, TABLE_STATS_NAME) == 0 ||
      strcmp(db_and_table, INDEX_STATS_NAME) == 0) {
    return (DB_SUCCESS);
  }

  dict_fs2utf8(db_and_table, db_utf8mb3, sizeof(db_utf8mb3), table_utf8mb3,
               sizeof(table_utf8mb3));

  dict_sys_mutex_exit();

  ret = dict_stats_delete_from_table_stats(db_utf8mb3, table_utf8mb3);

  if (ret == DB_SUCCESS) {
    ret = dict_stats_delete_from_index_stats(db_utf8mb3, table_utf8mb3);
  }

  dict_sys_mutex_enter();

  if (ret == DB_STATS_DO_NOT_EXIST) {
    ret = DB_SUCCESS;
  }

  if (ret != DB_SUCCESS) {
    snprintf(errstr, errstr_sz,
             "Unable to delete statistics for table %s.%s: %s."
             " They can be deleted later using"

             " DELETE FROM %s WHERE"
             " database_name = '%s' AND"
             " table_name = '%s';"

             " DELETE FROM %s WHERE"
             " database_name = '%s' AND"
             " table_name = '%s';",

             db_utf8mb3, table_utf8mb3, ut_strerr(ret),

             INDEX_STATS_NAME_PRINT, db_utf8mb3, table_utf8mb3,

             TABLE_STATS_NAME_PRINT, db_utf8mb3, table_utf8mb3);
  }

  return (ret);
}

/** Executes
 UPDATE mysql.innodb_table_stats SET
 database_name = '...', table_name = '...'
 WHERE database_name = '...' AND table_name = '...';
 Creates its own transaction and commits it.
 @return DB_SUCCESS or error code */
static inline dberr_t dict_stats_rename_table_in_table_stats(
    const char *old_dbname_utf8mb3,    /*!< in: database name, e.g. 'olddb' */
    const char *old_tablename_utf8mb3, /*!< in: table name, e.g. 'oldtable' */
    const char *new_dbname_utf8mb3,    /*!< in: database name, e.g. 'newdb' */
    const char *new_tablename_utf8mb3) /*!< in: table name, e.g. 'newtable' */
{
  pars_info_t *pinfo;
  dberr_t ret;

  ut_ad(rw_lock_own(dict_operation_lock, RW_LOCK_X));

  pinfo = pars_info_create();

  pars_info_add_str_literal(pinfo, "old_dbname_utf8mb3", old_dbname_utf8mb3);
  pars_info_add_str_literal(pinfo, "old_tablename_utf8mb3",
                            old_tablename_utf8mb3);
  pars_info_add_str_literal(pinfo, "new_dbname_utf8mb3", new_dbname_utf8mb3);
  pars_info_add_str_literal(pinfo, "new_tablename_utf8mb3",
                            new_tablename_utf8mb3);

  ret = dict_stats_exec_sql(pinfo,
                            "PROCEDURE RENAME_TABLE_IN_TABLE_STATS () IS\n"
                            "BEGIN\n"
                            "UPDATE \"" TABLE_STATS_NAME
                            "\" SET\n"
                            "database_name = :new_dbname_utf8mb3,\n"
                            "table_name = :new_tablename_utf8mb3\n"
                            "WHERE\n"
                            "database_name = :old_dbname_utf8mb3 AND\n"
                            "table_name = :old_tablename_utf8mb3;\n"
                            "END;\n",
                            nullptr);

  return (ret);
}

/** Executes
 UPDATE mysql.innodb_index_stats SET
 database_name = '...', table_name = '...'
 WHERE database_name = '...' AND table_name = '...';
 Creates its own transaction and commits it.
 @return DB_SUCCESS or error code */
static inline dberr_t dict_stats_rename_table_in_index_stats(
    const char *old_dbname_utf8mb3,    /*!< in: database name, e.g. 'olddb' */
    const char *old_tablename_utf8mb3, /*!< in: table name, e.g. 'oldtable' */
    const char *new_dbname_utf8mb3,    /*!< in: database name, e.g. 'newdb' */
    const char *new_tablename_utf8mb3) /*!< in: table name, e.g. 'newtable' */
{
  pars_info_t *pinfo;
  dberr_t ret;

  ut_ad(rw_lock_own(dict_operation_lock, RW_LOCK_X));

  pinfo = pars_info_create();

  pars_info_add_str_literal(pinfo, "old_dbname_utf8mb3", old_dbname_utf8mb3);
  pars_info_add_str_literal(pinfo, "old_tablename_utf8mb3",
                            old_tablename_utf8mb3);
  pars_info_add_str_literal(pinfo, "new_dbname_utf8mb3", new_dbname_utf8mb3);
  pars_info_add_str_literal(pinfo, "new_tablename_utf8mb3",
                            new_tablename_utf8mb3);

  ret = dict_stats_exec_sql(pinfo,
                            "PROCEDURE RENAME_TABLE_IN_INDEX_STATS () IS\n"
                            "BEGIN\n"
                            "UPDATE \"" INDEX_STATS_NAME
                            "\" SET\n"
                            "database_name = :new_dbname_utf8mb3,\n"
                            "table_name = :new_tablename_utf8mb3\n"
                            "WHERE\n"
                            "database_name = :old_dbname_utf8mb3 AND\n"
                            "table_name = :old_tablename_utf8mb3;\n"
                            "END;\n",
                            nullptr);

  return (ret);
}

/** Renames a table in InnoDB persistent stats storage.
 This function creates its own transaction and commits it.
 @return DB_SUCCESS or error code */
dberr_t dict_stats_rename_table(
    const char *old_name, /*!< in: old name, e.g. 'db/table' */
    const char *new_name, /*!< in: new name, e.g. 'db/table' */
    char *errstr,         /*!< out: error string if != DB_SUCCESS
                          is returned */
    size_t errstr_sz)     /*!< in: errstr size */
{
  char old_db_utf8mb3[dict_name::MAX_DB_UTF8MB3_LEN];
  char new_db_utf8mb3[dict_name::MAX_DB_UTF8MB3_LEN];
  char old_table_utf8mb3[dict_name::MAX_TABLE_UTF8MB3_LEN];
  char new_table_utf8mb3[dict_name::MAX_TABLE_UTF8MB3_LEN];
  dberr_t ret;

  ut_ad(!rw_lock_own(dict_operation_lock, RW_LOCK_X));

  /* skip innodb_table_stats and innodb_index_stats themselves */
  if (strcmp(old_name, TABLE_STATS_NAME) == 0 ||
      strcmp(old_name, INDEX_STATS_NAME) == 0 ||
      strcmp(new_name, TABLE_STATS_NAME) == 0 ||
      strcmp(new_name, INDEX_STATS_NAME) == 0) {
    return (DB_SUCCESS);
  }

  dict_fs2utf8(old_name, old_db_utf8mb3, sizeof(old_db_utf8mb3),
               old_table_utf8mb3, sizeof(old_table_utf8mb3));

  dict_fs2utf8(new_name, new_db_utf8mb3, sizeof(new_db_utf8mb3),
               new_table_utf8mb3, sizeof(new_table_utf8mb3));

  rw_lock_x_lock(dict_operation_lock, UT_LOCATION_HERE);

  ulint n_attempts = 0;
  do {
    n_attempts++;

    ret = dict_stats_rename_table_in_table_stats(
        old_db_utf8mb3, old_table_utf8mb3, new_db_utf8mb3, new_table_utf8mb3);

    if (ret == DB_DUPLICATE_KEY) {
      dict_stats_delete_from_table_stats(new_db_utf8mb3, new_table_utf8mb3);
    }

    if (ret == DB_STATS_DO_NOT_EXIST) {
      ret = DB_SUCCESS;
    }

    if (ret != DB_SUCCESS) {
      rw_lock_x_unlock(dict_operation_lock);
      std::this_thread::sleep_for(std::chrono::milliseconds(200));
      rw_lock_x_lock(dict_operation_lock, UT_LOCATION_HERE);
    }
  } while ((ret == DB_DEADLOCK || ret == DB_DUPLICATE_KEY ||
            ret == DB_LOCK_WAIT_TIMEOUT) &&
           n_attempts < 5);

  if (ret != DB_SUCCESS) {
    snprintf(errstr, errstr_sz,
             "Unable to rename statistics from"
             " %s.%s to %s.%s in %s: %s."
             " They can be renamed later using"

             " UPDATE %s SET"
             " database_name = '%s',"
             " table_name = '%s'"
             " WHERE"
             " database_name = '%s' AND"
             " table_name = '%s';",

             old_db_utf8mb3, old_table_utf8mb3, new_db_utf8mb3,
             new_table_utf8mb3, TABLE_STATS_NAME_PRINT, ut_strerr(ret),

             TABLE_STATS_NAME_PRINT, new_db_utf8mb3, new_table_utf8mb3,
             old_db_utf8mb3, old_table_utf8mb3);
    rw_lock_x_unlock(dict_operation_lock);
    return (ret);
  }
  /* else */

  n_attempts = 0;
  do {
    n_attempts++;

    ret = dict_stats_rename_table_in_index_stats(
        old_db_utf8mb3, old_table_utf8mb3, new_db_utf8mb3, new_table_utf8mb3);

    if (ret == DB_DUPLICATE_KEY) {
      dict_stats_delete_from_index_stats(new_db_utf8mb3, new_table_utf8mb3);
    }

    if (ret == DB_STATS_DO_NOT_EXIST) {
      ret = DB_SUCCESS;
    }

    if (ret != DB_SUCCESS) {
      rw_lock_x_unlock(dict_operation_lock);
      std::this_thread::sleep_for(std::chrono::milliseconds(200));
      rw_lock_x_lock(dict_operation_lock, UT_LOCATION_HERE);
    }
  } while ((ret == DB_DEADLOCK || ret == DB_DUPLICATE_KEY ||
            ret == DB_LOCK_WAIT_TIMEOUT) &&
           n_attempts < 5);

  rw_lock_x_unlock(dict_operation_lock);

  if (ret != DB_SUCCESS) {
    snprintf(errstr, errstr_sz,
             "Unable to rename statistics from"
             " %s.%s to %s.%s in %s: %s."
             " They can be renamed later using"

             " UPDATE %s SET"
             " database_name = '%s',"
             " table_name = '%s'"
             " WHERE"
             " database_name = '%s' AND"
             " table_name = '%s';",

             old_db_utf8mb3, old_table_utf8mb3, new_db_utf8mb3,
             new_table_utf8mb3, INDEX_STATS_NAME_PRINT, ut_strerr(ret),

             INDEX_STATS_NAME_PRINT, new_db_utf8mb3, new_table_utf8mb3,
             old_db_utf8mb3, old_table_utf8mb3);
  }

  return (ret);
}

/** Renames an index in InnoDB persistent stats storage.
 This function creates its own transaction and commits it.
 @return DB_SUCCESS or error code. DB_STATS_DO_NOT_EXIST will be returned
 if the persistent stats do not exist. */
dberr_t dict_stats_rename_index(
    const dict_table_t *table,  /*!< in: table whose index
                                is renamed */
    const char *old_index_name, /*!< in: old index name */
    const char *new_index_name) /*!< in: new index name */
{
  rw_lock_x_lock(dict_operation_lock, UT_LOCATION_HERE);

  char dbname_utf8mb3[dict_name::MAX_DB_UTF8MB3_LEN];
  char tablename_utf8mb3[dict_name::MAX_TABLE_UTF8MB3_LEN];

  dict_fs2utf8(table->name.m_name, dbname_utf8mb3, sizeof(dbname_utf8mb3),
               tablename_utf8mb3, sizeof(tablename_utf8mb3));

  pars_info_t *pinfo;

  pinfo = pars_info_create();

  pars_info_add_str_literal(pinfo, "dbname_utf8mb3", dbname_utf8mb3);
  pars_info_add_str_literal(pinfo, "tablename_utf8mb3", tablename_utf8mb3);
  pars_info_add_str_literal(pinfo, "new_index_name", new_index_name);
  pars_info_add_str_literal(pinfo, "old_index_name", old_index_name);

  dberr_t ret;

  ret = dict_stats_exec_sql(pinfo,
                            "PROCEDURE RENAME_INDEX_IN_INDEX_STATS () IS\n"
                            "BEGIN\n"
                            "UPDATE \"" INDEX_STATS_NAME
                            "\" SET\n"
                            "index_name = :new_index_name\n"
                            "WHERE\n"
                            "database_name = :dbname_utf8mb3 AND\n"
                            "table_name = :tablename_utf8mb3 AND\n"
                            "index_name = :old_index_name;\n"
                            "END;\n",
                            nullptr);

  rw_lock_x_unlock(dict_operation_lock);

  return (ret);
}

TableStatsRecord::TableStatsRecord() { m_heap = nullptr; }

TableStatsRecord::~TableStatsRecord() {
  if (m_heap != nullptr) {
    mem_heap_free(m_heap);
  }
}

uint64_t TableStatsRecord::get_n_rows() const { return (m_n_rows); }

void TableStatsRecord::set_n_rows(uint64_t no_of_rows) {
  m_n_rows = no_of_rows;
}

ulint TableStatsRecord::get_clustered_index_size() const {
  return (m_clustered_index_size);
}

void TableStatsRecord::set_clustered_index_size(ulint clust_size) {
  m_clustered_index_size = clust_size;
}

ulint TableStatsRecord::get_sum_of_other_index_size() const {
  return (m_sum_of_other_index_sizes);
}

void TableStatsRecord::set_sum_of_other_index_size(
    ulint sum_of_other_index_size) {
  m_sum_of_other_index_sizes = sum_of_other_index_size;
}

char *TableStatsRecord::get_db_name() const { return (m_db_name); }

void TableStatsRecord::set_db_name(const byte *data, ulint len) {
  if (m_heap == nullptr) {
    m_heap = mem_heap_create(MAX_DATABASE_NAME_LEN + 1, UT_LOCATION_HERE);
  }

  m_db_name = static_cast<char *>(mem_heap_dup(m_heap, data, len + 1));
  m_db_name[len] = '\0';
}

char *TableStatsRecord::get_tbl_name() const { return (m_tbl_name); }

void TableStatsRecord::set_tbl_name(const byte *data, ulint len) {
  if (m_heap == nullptr) {
    m_heap = mem_heap_create(MAX_TABLE_NAME_LEN + 1, UT_LOCATION_HERE);
  }

  m_tbl_name = static_cast<char *>(mem_heap_dup(m_heap, data, len + 1));
  m_tbl_name[len] = '\0';
}

void TableStatsRecord::set_data(const byte *data, ulint col_offset, ulint len) {
  dict_table_t *table = dict_sys->table_stats;
  dict_index_t *index = table->first_index();
  ulint value;
  uint64_t n_row;
  ulint index_col_offset = index->get_col_no(col_offset);

  switch (index_col_offset) {
    case DB_NAME_COL_NO:
      set_db_name(data, len);
      break;
    case TABLE_NAME_COL_NO:
      set_tbl_name(data, len);
      break;
    case N_ROWS_COL_NO:
      n_row = mach_read_from_8(data);
      set_n_rows(n_row);
      break;
    case CLUST_INDEX_SIZE_COL_NO:
      value = mach_read_from_8(data);
      set_clustered_index_size(value);
      break;
    case SUM_OF_OTHER_INDEX_SIZE_COL_NO:
      value = mach_read_from_8(data);
      set_sum_of_other_index_size(value);
      break;
    default:
      break;
  }
}

/** tests @{ */
#ifdef UNIV_COMPILE_TEST_FUNCS
/** save/fetch aux macros @{ */
#define TEST_DATABASE_NAME "foobardb"
#define TEST_TABLE_NAME "test_dict_stats"

#define TEST_N_ROWS 111
#define TEST_CLUSTERED_INDEX_SIZE 222
#define TEST_SUM_OF_OTHER_INDEX_SIZES 333

#define TEST_IDX1_NAME "tidx1"
#define TEST_IDX1_COL1_NAME "tidx1_col1"
#define TEST_IDX1_INDEX_SIZE 123
#define TEST_IDX1_N_LEAF_PAGES 234
#define TEST_IDX1_N_DIFF1 50
#define TEST_IDX1_N_DIFF1_SAMPLE_SIZE 500

#define TEST_IDX2_NAME "tidx2"
#define TEST_IDX2_COL1_NAME "tidx2_col1"
#define TEST_IDX2_COL2_NAME "tidx2_col2"
#define TEST_IDX2_COL3_NAME "tidx2_col3"
#define TEST_IDX2_COL4_NAME "tidx2_col4"
#define TEST_IDX2_INDEX_SIZE 321
#define TEST_IDX2_N_LEAF_PAGES 432
#define TEST_IDX2_N_DIFF1 60
#define TEST_IDX2_N_DIFF1_SAMPLE_SIZE 600
#define TEST_IDX2_N_DIFF2 61
#define TEST_IDX2_N_DIFF2_SAMPLE_SIZE 610
#define TEST_IDX2_N_DIFF3 62
#define TEST_IDX2_N_DIFF3_SAMPLE_SIZE 620
#define TEST_IDX2_N_DIFF4 63
#define TEST_IDX2_N_DIFF4_SAMPLE_SIZE 630
/** @} */

/** test_dict_stats_save() @{ */
void test_dict_stats_save() {
  dict_table_t table;
  dict_index_t index1;
  dict_field_t index1_fields[1];
  uint64_t index1_stat_n_diff_key_vals[1];
  uint64_t index1_stat_n_sample_sizes[1];
  dict_index_t index2;
  dict_field_t index2_fields[4];
  uint64_t index2_stat_n_diff_key_vals[4];
  uint64_t index2_stat_n_sample_sizes[4];
  dberr_t ret;

  /* craft a dummy dict_table_t */
  table.name.m_name = (char *)(TEST_DATABASE_NAME "/" TEST_TABLE_NAME);
  table.stat_n_rows = TEST_N_ROWS;
  table.stat_clustered_index_size = TEST_CLUSTERED_INDEX_SIZE;
  table.stat_sum_of_other_index_sizes = TEST_SUM_OF_OTHER_INDEX_SIZES;
  UT_LIST_INIT(table.indexes);
  UT_LIST_ADD_LAST(table.indexes, &index1);
  UT_LIST_ADD_LAST(table.indexes, &index2);
  ut_d(table.magic_n = DICT_TABLE_MAGIC_N);
  ut_d(index1.magic_n = DICT_INDEX_MAGIC_N);

  index1.name = TEST_IDX1_NAME;
  index1.table = &table;
  index1.cached = 1;
  index1.n_uniq = 1;
  index1.fields = index1_fields;
  index1.stat_n_diff_key_vals = index1_stat_n_diff_key_vals;
  index1.stat_n_sample_sizes = index1_stat_n_sample_sizes;
  index1.stat_index_size = TEST_IDX1_INDEX_SIZE;
  index1.stat_n_leaf_pages = TEST_IDX1_N_LEAF_PAGES;
  index1_fields[0].name = TEST_IDX1_COL1_NAME;
  index1_stat_n_diff_key_vals[0] = TEST_IDX1_N_DIFF1;
  index1_stat_n_sample_sizes[0] = TEST_IDX1_N_DIFF1_SAMPLE_SIZE;

  ut_d(index2.magic_n = DICT_INDEX_MAGIC_N);
  index2.name = TEST_IDX2_NAME;
  index2.table = &table;
  index2.cached = 1;
  index2.n_uniq = 4;
  index2.fields = index2_fields;
  index2.stat_n_diff_key_vals = index2_stat_n_diff_key_vals;
  index2.stat_n_sample_sizes = index2_stat_n_sample_sizes;
  index2.stat_index_size = TEST_IDX2_INDEX_SIZE;
  index2.stat_n_leaf_pages = TEST_IDX2_N_LEAF_PAGES;
  index2_fields[0].name = TEST_IDX2_COL1_NAME;
  index2_fields[1].name = TEST_IDX2_COL2_NAME;
  index2_fields[2].name = TEST_IDX2_COL3_NAME;
  index2_fields[3].name = TEST_IDX2_COL4_NAME;
  index2_stat_n_diff_key_vals[0] = TEST_IDX2_N_DIFF1;
  index2_stat_n_diff_key_vals[1] = TEST_IDX2_N_DIFF2;
  index2_stat_n_diff_key_vals[2] = TEST_IDX2_N_DIFF3;
  index2_stat_n_diff_key_vals[3] = TEST_IDX2_N_DIFF4;
  index2_stat_n_sample_sizes[0] = TEST_IDX2_N_DIFF1_SAMPLE_SIZE;
  index2_stat_n_sample_sizes[1] = TEST_IDX2_N_DIFF2_SAMPLE_SIZE;
  index2_stat_n_sample_sizes[2] = TEST_IDX2_N_DIFF3_SAMPLE_SIZE;
  index2_stat_n_sample_sizes[3] = TEST_IDX2_N_DIFF4_SAMPLE_SIZE;

  ret = dict_stats_save(&table, NULL, nullptr);

  ut_a(ret == DB_SUCCESS);

  printf(
      "\nOK: stats saved successfully, now go ahead and read"
      " what's inside %s and %s:\n\n",
      TABLE_STATS_NAME_PRINT, INDEX_STATS_NAME_PRINT);

  printf(
      "SELECT COUNT(*) = 1 AS table_stats_saved_successfully\n"
      "FROM %s\n"
      "WHERE\n"
      "database_name = '%s' AND\n"
      "table_name = '%s' AND\n"
      "n_rows = %d AND\n"
      "clustered_index_size = %d AND\n"
      "sum_of_other_index_sizes = %d;\n"
      "\n",
      TABLE_STATS_NAME_PRINT, TEST_DATABASE_NAME, TEST_TABLE_NAME, TEST_N_ROWS,
      TEST_CLUSTERED_INDEX_SIZE, TEST_SUM_OF_OTHER_INDEX_SIZES);

  printf(
      "SELECT COUNT(*) = 3 AS tidx1_stats_saved_successfully\n"
      "FROM %s\n"
      "WHERE\n"
      "database_name = '%s' AND\n"
      "table_name = '%s' AND\n"
      "index_name = '%s' AND\n"
      "(\n"
      " (stat_name = 'size' AND stat_value = %d AND"
      "  sample_size IS NULL) OR\n"
      " (stat_name = 'n_leaf_pages' AND stat_value = %d AND"
      "  sample_size IS NULL) OR\n"
      " (stat_name = 'n_diff_pfx01' AND stat_value = %d AND"
      "  sample_size = '%d' AND stat_description = '%s')\n"
      ");\n"
      "\n",
      INDEX_STATS_NAME_PRINT, TEST_DATABASE_NAME, TEST_TABLE_NAME,
      TEST_IDX1_NAME, TEST_IDX1_INDEX_SIZE, TEST_IDX1_N_LEAF_PAGES,
      TEST_IDX1_N_DIFF1, TEST_IDX1_N_DIFF1_SAMPLE_SIZE, TEST_IDX1_COL1_NAME);

  printf(
      "SELECT COUNT(*) = 6 AS tidx2_stats_saved_successfully\n"
      "FROM %s\n"
      "WHERE\n"
      "database_name = '%s' AND\n"
      "table_name = '%s' AND\n"
      "index_name = '%s' AND\n"
      "(\n"
      " (stat_name = 'size' AND stat_value = %d AND"
      "  sample_size IS NULL) OR\n"
      " (stat_name = 'n_leaf_pages' AND stat_value = %d AND"
      "  sample_size IS NULL) OR\n"
      " (stat_name = 'n_diff_pfx01' AND stat_value = %d AND"
      "  sample_size = '%d' AND stat_description = '%s') OR\n"
      " (stat_name = 'n_diff_pfx02' AND stat_value = %d AND"
      "  sample_size = '%d' AND stat_description = '%s,%s') OR\n"
      " (stat_name = 'n_diff_pfx03' AND stat_value = %d AND"
      "  sample_size = '%d' AND stat_description = '%s,%s,%s') OR\n"
      " (stat_name = 'n_diff_pfx04' AND stat_value = %d AND"
      "  sample_size = '%d' AND stat_description = '%s,%s,%s,%s')\n"
      ");\n"
      "\n",
      INDEX_STATS_NAME_PRINT, TEST_DATABASE_NAME, TEST_TABLE_NAME,
      TEST_IDX2_NAME, TEST_IDX2_INDEX_SIZE, TEST_IDX2_N_LEAF_PAGES,
      TEST_IDX2_N_DIFF1, TEST_IDX2_N_DIFF1_SAMPLE_SIZE, TEST_IDX2_COL1_NAME,
      TEST_IDX2_N_DIFF2, TEST_IDX2_N_DIFF2_SAMPLE_SIZE, TEST_IDX2_COL1_NAME,
      TEST_IDX2_COL2_NAME, TEST_IDX2_N_DIFF3, TEST_IDX2_N_DIFF3_SAMPLE_SIZE,
      TEST_IDX2_COL1_NAME, TEST_IDX2_COL2_NAME, TEST_IDX2_COL3_NAME,
      TEST_IDX2_N_DIFF4, TEST_IDX2_N_DIFF4_SAMPLE_SIZE, TEST_IDX2_COL1_NAME,
      TEST_IDX2_COL2_NAME, TEST_IDX2_COL3_NAME, TEST_IDX2_COL4_NAME);
}
/** @} */

/** test_dict_stats_fetch_from_ps() @{ */
void test_dict_stats_fetch_from_ps() {
  dict_table_t table;
  dict_index_t index1;
  uint64_t index1_stat_n_diff_key_vals[1];
  uint64_t index1_stat_n_sample_sizes[1];
  dict_index_t index2;
  uint64_t index2_stat_n_diff_key_vals[4];
  uint64_t index2_stat_n_sample_sizes[4];
  dberr_t ret;

  /* craft a dummy dict_table_t */
  table.name.m_name = (char *)(TEST_DATABASE_NAME "/" TEST_TABLE_NAME);
  UT_LIST_INIT(table.indexes);
  UT_LIST_ADD_LAST(table.indexes, &index1);
  UT_LIST_ADD_LAST(table.indexes, &index2);
  ut_d(table.magic_n = DICT_TABLE_MAGIC_N);

  index1.name = TEST_IDX1_NAME;
  ut_d(index1.magic_n = DICT_INDEX_MAGIC_N);
  index1.cached = 1;
  index1.n_uniq = 1;
  index1.stat_n_diff_key_vals = index1_stat_n_diff_key_vals;
  index1.stat_n_sample_sizes = index1_stat_n_sample_sizes;

  index2.name = TEST_IDX2_NAME;
  ut_d(index2.magic_n = DICT_INDEX_MAGIC_N);
  index2.cached = 1;
  index2.n_uniq = 4;
  index2.stat_n_diff_key_vals = index2_stat_n_diff_key_vals;
  index2.stat_n_sample_sizes = index2_stat_n_sample_sizes;

  ret = dict_stats_fetch_from_ps(&table);

  ut_a(ret == DB_SUCCESS);

  ut_a(table.stat_n_rows == TEST_N_ROWS);
  ut_a(table.stat_clustered_index_size == TEST_CLUSTERED_INDEX_SIZE);
  ut_a(table.stat_sum_of_other_index_sizes == TEST_SUM_OF_OTHER_INDEX_SIZES);

  ut_a(index1.stat_index_size == TEST_IDX1_INDEX_SIZE);
  ut_a(index1.stat_n_leaf_pages == TEST_IDX1_N_LEAF_PAGES);
  ut_a(index1_stat_n_diff_key_vals[0] == TEST_IDX1_N_DIFF1);
  ut_a(index1_stat_n_sample_sizes[0] == TEST_IDX1_N_DIFF1_SAMPLE_SIZE);

  ut_a(index2.stat_index_size == TEST_IDX2_INDEX_SIZE);
  ut_a(index2.stat_n_leaf_pages == TEST_IDX2_N_LEAF_PAGES);
  ut_a(index2_stat_n_diff_key_vals[0] == TEST_IDX2_N_DIFF1);
  ut_a(index2_stat_n_sample_sizes[0] == TEST_IDX2_N_DIFF1_SAMPLE_SIZE);
  ut_a(index2_stat_n_diff_key_vals[1] == TEST_IDX2_N_DIFF2);
  ut_a(index2_stat_n_sample_sizes[1] == TEST_IDX2_N_DIFF2_SAMPLE_SIZE);
  ut_a(index2_stat_n_diff_key_vals[2] == TEST_IDX2_N_DIFF3);
  ut_a(index2_stat_n_sample_sizes[2] == TEST_IDX2_N_DIFF3_SAMPLE_SIZE);
  ut_a(index2_stat_n_diff_key_vals[3] == TEST_IDX2_N_DIFF4);
  ut_a(index2_stat_n_sample_sizes[3] == TEST_IDX2_N_DIFF4_SAMPLE_SIZE);

  printf("OK: fetch successful\n");
}
/** @} */

/** test_dict_stats_all() @{ */
void test_dict_stats_all() {
  test_dict_stats_save();

  test_dict_stats_fetch_from_ps();
}
/** @} */

#endif /* UNIV_COMPILE_TEST_FUNCS */
/** @} */
